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Inverter User's Manual
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ZVF9-G & ZVF9-P Series
Inverter User's Manual
INVERTERINVERTER
Foreword
l Thank you very much for your purchase of ZVF9 series of inverters.l This manual introduces the installation, operation, function setting, trouble shooting and etc. of inverters.l Incorrect installation or use may result in damage or other accidents. Do read all instructions in detail before installing or operating.l Please forward this manual to the end user, and keep it handy for quick reference.l If there are any doubts or questions, please contact the Technical Service Center of Company.
Foreword
l Thank you very much for your purchase of ZVF9 series of inverters.l This manual introduces the installation, operation, function setting, trouble shooting and etc. of inverters.l Incorrect installation or use may result in damage or other accidents. Do read all instructions in detail before installing or operating.l Please forward this manual to the end user, and keep it handy for quick reference.l If there are any doubts or questions, please contact the Technical Service Center of Company.
Table of ContentsTable of Contents
Chapter 1 Safety Instruction 1
1.1 Safety Symbols and Definitions 1
1.2 Application Range 2
1.3 Installation Ambient 2
1.4 Cautions for Installing 3
1.5 Cautions for Operation 5
1.6 Cautions for Disposing of the Inverter 8
Chapter 2 Introduction to the Product 9
2.1 Product Inspection upon Arrival 9
2.2 Diagram of the Model 9
2.3 Specifications Label 9
2.4 Outline and Structure 10
2.5 Models and Specifications 13
2.6 Technical Indications 15
Chapter 3 Installation and Wiring 18
3.1 Inverter Mounting 18
3.2 Inverter Spare Parts Dismantling and Mounting 20
3.3 Inverter Wiring 25
3.4 Inverter System Wiring 36
Chapter 4 Operation Panel and its Operation 40
4.1 Operation Panel and Instructions 40
4.2 Display of Monitoring Parameters 47
4.3 Display of Trouble Parameters 49
Chapter 1 Safety Instruction 1
Chapter 2 Introduction to the Product 9
Chapter 3 Installation and Wiring 18
Chapter 4 Operation Panel and its Operation 40
1.1 Safety Symbols and Definitions 1
1.2 Application Range 2
1.3 Installation Ambient 2
1.4 Cautions for Installing 3
1.5 Cautions for Operation 5
1.6 Cautions for Disposing of the Inverter 8
2.1 Product Inspection upon Arrival 9
2.2 Diagram of the Model 9
2.3 Specifications Label 9
2.4 Outline and Structure 10
2.5 Models and Specifications 13
2.6 Technical Indications 15
3.1 Inverter Mounting 18
3.2 Inverter Spare Parts Dismantling and Mounting 20
3.3 Inverter Wiring 25
3.4 Inverter System Wiring 36
4.1 Operation Panel and Instructions 40
4.2 Display of Monitoring Parameters 47
4.3 Display of Trouble Parameters 49
Chapter 5 Operation of the Inverter 50
5.1 Trial Operation 50
5.2 Cautions for Operation 52
5.3 Operation Examples 54
Chapter 6 Introduction to Function Parameters 61
6.1 Schedule of Function Parameters 62
6.2 Detailed Instructions on Function Parameters 75
Chapter 7Common Problems, Anomalies and Troubleshooting 113
7.1 Diagnostic Trouble Codes and Troubleshooting 113
7.2 Anomalies and Solutions 116
Chapter 8 Inverter Inspection and Maintenance 117
8.1 Inspection and Maintenance 117
8.2 Replacement of Wearing Parts 120
8.3 Storage of Inverter 121
Chapter 9 Outline Dimensions & Mounting Dimensions 122
9.1 Inverter Outline Dimensions & Mounting Dimensions 122
9.2 Operator Panel Outline Dimensions & Mounting Dimensions 126
Chapter 10 Quality Warranty 128
10.1 Inverter Quality Warranty 128
Appendices 129
Appendix 1 Parts Choosing 132
Appendix 2 EMI Prevention 138
Appendix 3 User's Parameter Amendment Record 138
Appendix 4 Warranty 141
Chapter 5 Operation of the Inverter 50
Chapter 6 Introduction to Function Parameters 61
Chapter 7Common Problems, Anomalies and Troubleshooting 113
Chapter 8 Inverter Inspection and Maintenance 117
121
Chapter 9 Outline Dimensions & Mounting Dimensions 122
Chapter 10 Quality Warranty 128
Appendices 129
5.1 Trial Operation 50
5.2 Cautions for Operation 52
5.3 Operation Examples 54
6.1 Schedule of Function Parameters 62
6.2 Detailed Instructions on Function Parameters 75
7.1 Diagnostic Trouble Codes and Troubleshooting 113
7.2 Anomalies and Solutions 116
8.1 Inspection and Maintenance 117
8.2 Replacement of Wearing Parts 120
8.3 Storage of Inverter
9.1 Inverter Outline Dimensions & Mounting Dimensions 122
9.2 Operator Panel Outline Dimensions & Mounting Dimensions 126
10.1 Inverter Quality Warranty 128
Appendix 1 Parts Choosing 132
Appendix 2 EMI Prevention 138
Appendix 3 User's Parameter Amendment Record 138
Appendix 4 Warranty 141
Table of ContentsTable of Contents
Table of ContentsTable of Contents Table of ContentsTable of Contents
Chapter 1 Safety InstructionsChapter 1 Safety Instructions
Chapter 1 Safety Instructions
1.1 Safety Symbols and Definitions
The safety instructions described in this manual are very important. To avoid any error that may result in damage to equipment, injury to personnel or loss of property, do read and clearly understand all of the safety symbols, symbol definitions and be sure to observe the indicated safety instructions below.
Chapter 1 Safety Instructions
1.1 Safety Symbols and Definitions
The safety instructions described in this manual are very important. To avoid any error that may result in damage to equipment, injury to personnel or loss of property, do read and clearly understand all of the safety symbols, symbol definitions and be sure to observe the indicated safety instructions below.
Safety SymbolsSafety Symbols Symbol DefinitionsSymbol Definitions
HIGH VOLTAGE: This symbol indicates hazardous HIGH VOLTAGE. Any incorrect operation may result in serious damage to the equipment or death to personnel.
HIGH VOLTAGE: This symbol indicates hazardous HIGH VOLTAGE. Any incorrect operation may result in serious damage to the equipment or death to personnel.
WARNING: This symbol indicates that any incorrect
operation can result in damage to the equipment or minor to
moderate injury to personnel.
WARNING: This symbol indicates that any incorrect
operation can result in damage to the equipment or minor to
moderate injury to personnel.
CAUTION: This symbol calls your attention to follow the i n s t r u c t i o n s w h i l e i n o p e r a t i o n o r i n u s e .CAUTION: This symbol calls your attention to follow the i n s t r u c t i o n s w h i l e i n o p e r a t i o n o r i n u s e .
TIP: This symbol calls attention to some useful messages for the user. TIP: This symbol calls attention to some useful messages for the user.
FORBIDDEN: This symbol indicates anything forbidden to do.FORBIDDEN: This symbol indicates anything forbidden to do.
COMPULSORY: This symbol indicates something must do.COMPULSORY: This symbol indicates something must do.
1.2 Application Range1.2 Application Range
This inverter can not be used in the equipment that may result in threat or injury to personnel due to inverter trouble or error, such as nuclear power control equipment, aviation equipment, transportation equipment, life supporting system, safety equipment, weapon system and etc. Please consult Ziri Company before using it for special purpose.
This product is made under strict quality control and supervision. But when used in some key equipment, protective measures should be taken to avoid further extension of accident due to inverter trouble.
This inverter can not be used in the equipment that may result in threat or injury to personnel due to inverter trouble or error, such as nuclear power control equipment, aviation equipment, transportation equipment, life supporting system, safety equipment, weapon system and etc. Please consult Ziri Company before using it for special purpose.
This product is made under strict quality control and supervision. But when used in some key equipment, protective measures should be taken to avoid further extension of accident due to inverter trouble.
This inverter is applicable to general industrial purpose
three-phase AC asynchronic electric motor.
This inverter is applicable to general industrial purpose
three-phase AC asynchronic electric motor.
1.3 Installation Ambient1.3 Installation Ambient
Be sure to install the inverter in a well-ventilated indoor location. To get the best cooling effect, it is recommended to fix the inverter vertically, and extra ventilation devices are needed when installed horizontally.
Be sure that the ambient temperature is between -10~45 C. If the temperature is higher than 45 C, please remove the upper cover. If the temperature is higher than 50 C, forced heat radiation or derating is needed from the external. It is recommended not to use the inverter in such a high temperature. Otherwise, it may greatly reduce the service life of the inverter.
The ambient humidity is required to be lower than 90% without dew condensation.
The inverter shall be installed in a place where the vibration is less than 0.5G. Otherwise, it may fall and cause damage to the equipment. It is also noteworthy that the inverter could not bear any sudden bump.
The inverter should be kept away from electromagnetic interference (EMI), flammable and explosive ambient.
Be sure to install the inverter in a well-ventilated indoor location. To get the best cooling effect, it is recommended to fix the inverter vertically, and extra ventilation devices are needed when installed horizontally.
Be sure that the ambient temperature is between -10~45 C. If the temperature is higher than 45 C, please remove the upper cover. If the temperature is higher than 50 C, forced heat radiation or derating is needed from the external. It is recommended not to use the inverter in such a high temperature. Otherwise, it may greatly reduce the service life of the inverter.
The ambient humidity is required to be lower than 90% without dew condensation.
The inverter shall be installed in a place where the vibration is less than 0.5G. Otherwise, it may fall and cause damage to the equipment. It is also noteworthy that the inverter could not bear any sudden bump.
The inverter should be kept away from electromagnetic interference (EMI), flammable and explosive ambient.
1.4 Cautions for Installing1.4 Cautions for Installing
Be sure to install the inverter on metallic materials (i.e., metal). Otherwise, there is the danger of fire.
Bu sure not to let the foreign matter enter the inverter, such as wire clippings, spatter from welding, metal shavings and etc. Otherwise, there is the danger of getting burned due to short circuit.
Be sure to install the inverter on metallic materials (i.e., metal). Otherwise, there is the danger of fire.
Bu sure not to let the foreign matter enter the inverter, such as wire clippings, spatter from welding, metal shavings and etc. Otherwise, there is the danger of getting burned due to short circuit.
Do not operate electrical equipment with wet hands.
Do not operate wiring unless the power supply is completely off.
Do not open the front cover or perform wiring while the inverter
is powered ON. Otherwise, there is the danger of electric shock.
Do wait at least 10 minutes after the power is disconnected
before performing the work of wiring or inspection. Otherwise,
there is the danger of electric shock.
Do not operate electrical equipment with wet hands.
Do not operate wiring unless the power supply is completely off.
Do not open the front cover or perform wiring while the inverter
is powered ON. Otherwise, there is the danger of electric shock.
Do wait at least 10 minutes after the power is disconnected
before performing the work of wiring or inspection. Otherwise,
there is the danger of electric shock.
Do not install or operate if the inverter is damaged or has parts
missing to prevent injury to personnel or loss of property.
The main loop terminal should be tightly connected to the cable.
Otherwise, the inverter may be damaged arising from loose
connection.
The ground terminal must be reliably and properly grounded to
ensure security. To avoid common ground impedance, multi-
piece inverters should be grounded at one shared point, as
shown in Figure 1-1.
Do not install or operate if the inverter is damaged or has parts
missing to prevent injury to personnel or loss of property.
The main loop terminal should be tightly connected to the cable.
Otherwise, the inverter may be damaged arising from loose
connection.
The ground terminal must be reliably and properly grounded to
ensure security. To avoid common ground impedance, multi-
piece inverters should be grounded at one shared point, as
shown in Figure 1-1.
Chapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety Instructions
CAUTIONCAUTION
WARNINGWARNING
WARNINGWARNING
WARNINGWARNINGCAUTIONCAUTION
HAZARD
1.5 Cautions for Operation1.5 Cautions for Operation
Do not operate electrical equipment with wet hands.
An inverter stored for half a year or longer should be given
powerup test before use so that the main circuit filter capacitor
could be recovered.When the inverter is in the state of powerup,
it is necessary to raise the voltage gradually to the rated value
with a voltage regulator. Generally, the charging time should be
controlled within 1~2 hours. Otherwise, there is the danger of
electric shock or exposure.
Do not touch the inner side of the inverter while the power is
ON, nor put any foreign matter, i.e., rod or other matter inside
the inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Do not open the front cover while the inverter is powered ON.
Otherwise, there is the danger of electric shock.
Be careful to select the Restart Mode. Otherwise, there is the
danger of personnel death.
Do not operate electrical equipment with wet hands.
An inverter stored for half a year or longer should be given
powerup test before use so that the main circuit filter capacitor
could be recovered. When the inverter is in the state of powerup,
it is necessary to raise the voltage gradually to the rated value
with a voltage regulator. Generally, the charging time should be
controlled within 1~2 hours. Otherwise, there is the danger of
electric shock or exposure.
Do not touch the inner side of the inverter while the power is
ON, nor put any foreign matter, i.e., rod or other matter inside
the inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Do not open the front cover while the inverter is powered ON.
Otherwise, there is the danger of electric shock.
Be careful to select the Restart Mode. Otherwise, there is the
danger of personnel death.
CAUTIONCAUTION
It is not advisable to install an electromagnetic contactor in
the side of output power supply, because the operation of open
and close to the contactor when the motor is running may cause
damage to the inverter arising from over-voltage produced
during this process. But it is still necessary to install a contactor
if one of the following three points occurs:
The system of frequency converting governor used to control
energy-saving usually works at a rated rotation speed. To run the
governor economically, there is a must to remove the inverter.
The inverter participates in some import procedure and cannot
stop operating for a long period of time. To realize free shift in
various control systems and improve the reliability of these
systems, there is a must to install a contactor.
When an inverter controls several motors, there is a must to
install a contactor.
It is not advisable to install an electromagnetic contactor in
the side of output power supply, because the operation of open
and close to the contactor when the motor is running may cause
damage to the inverter arising from over-voltage produced
during this process. But it is still necessary to install a contactor
if one of the following three points occurs:
The system of frequency converting governor used to control
energy-saving usually works at a rated rotation speed. To run the
governor economically, there is a must to remove the inverter.
The inverter participates in some import procedure and cannot
stop operating for a long period of time. To realize free shift in
various control systems and improve the reliability of these
systems, there is a must to install a contactor.
When an inverter controls several motors, there is a must to
install a contactor.
HAZARDHAZARD
Fig. 1-1Fig. 1-1
INVERTERINVERTER Proper grounding methods
Proper grounding methods
Grounding bus bar (Connect to the ground at one shared point)Grounding bus bar (Connect to the ground at one shared point)
COMPULSORYCOMPULSORY
DO NOT connect control terminals (except terminals marked TA , TB and TC ) to AC 220V power supply, which
may cause damage to the inverter.DO NOT connect AC power supply to the output terminals
marked U , V and W . Otherwise, it may cause damage to the inverter, as shown in Figure 1-2
DO NOT connect control terminals (except terminals marked TA , TB and TC ) to AC 220V power supply, which
may cause damage to the inverter.DO NOT connect AC power supply to the output terminals
marked U , V and W . Otherwise, it may cause damage to the inverter, as shown in Figure 1-2
DO install a no-fuse circuit breaker or leakage protective circuit breaker in the side of inverter input power supply to prevent expanding of accident due to an inverter problem.
DO install a no-fuse circuit breaker or leakage protective circuit breaker in the side of inverter input power supply to prevent expanding of accident due to an inverter problem.
Fig. Fig.
Chapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety Instructions
INVERTERINVERTERINVERTERINVERTER
FORBIDDENFORBIDDEN
FORBIDDENFORBIDDEN
Three-phase AC Power SupplyThree-phase AC Power Supply
INVERTERINVERTER
It is not advisory to run the reduction box, gear and other
mechanism that need lubricating at low speed for a long period.
Otherwise, it may reduce the service life of these equipment or even
damage the equipment.
Derating should be done before use due to less effective of heat
dissipation when a general motor runs at a low frequency. If it is a
constant torque load, then a forced method or a special variable
frequency motor should be used to release heat.
DO cut off the power supply of an inverter set aside for a long
time to avoid foreign matter or other things enter in it which may
cause damage to the inverter or even lead to fire.
The output voltage of inverter is PWM impulse wave. DO NOT
install a capacitor or surge current sink (i.e., a varistor) in the
inverter output port. Otherwise, there is the danger of fault tripping
of the inverter or damage to its power elements. DO remove such
kind of things if already installed. See Figure 1-3 below.
If the inverter runs at a frequency higher than 50Hz, DO confirm
it is within the speed range acceptable by your motor bearing and
mechanical device. Otherwise, there is the danger of damage to the
motor.
If the inverter runs at a frequency higher than 50Hz, DO confirm
it is within the speed range acceptable by your motor bearing and
mechanical device. Otherwise, there is the danger of damage to the
motor.
It is not advisory to run the reduction box, gear and other
mechanism that need lubricating at low speed for a long period.
Otherwise, it may reduce the service life of these equipment or even
damage the equipment.
Derating should be done before use due to less effective of heat
dissipation when a general motor runs at a low frequency. If it is a
constant torque load, then a forced method or a special variable
frequency motor should be used to release heat.
DO cut off the power supply of an inverter set aside for a long
time to avoid foreign matter or other things enter in it which may
cause damage to the inverter or even lead to fire.
The output voltage of inverter is PWM impulse wave. DO NOT
install a capacitor or surge current sink (i.e., a varistor) in the
inverter output port. Otherwise, there is the danger of fault tripping
of the inverter or damage to its power elements. DO remove such
kind of things if already installed. See Figure 1-3 below.
WARNINGWARNING
MM~~
U
V
W
U
V
W
Power factor compensation capacitorPower factor compensation capacitor
Surge current sinkSurge current sink
Motor insulation should be checked before the inverter is used for the first use or reused after a long-term idle. Be sure the insulation resistance measured is no lower than 5ÙIf the inverter is used beyond the range of allowable working voltage, then an extra step-up or step-down voltage transformer shall be configured.Due to thin air in a place where the altitude is higher than 1,000m, the heat dissipation of inverter will be less effective. Hence derating should be done before use. In general, when the height rises by 1,000m, the rated voltage of the inverter shall reduce by 10%. Refer to Figure 1-4 for details of the derating curve.
Motor insulation should be checked before the inverter is used for the first use or reused after a lon
If the inverter is used beyond the range of allowable working voltage, then an extra step-up or step-down voltage transformer shall be configured.Due to thin air in a place where the altitude is higher than 1,000m, the heat dissipation of inverter will be less effective. Hence derating should be done before use. In general, when the height rises by 1,000m, the rated voltage of the inverter shall reduce by 10%. Refer to Figure 1-4 for details of the derating curve.
g-term idle. Be sure the insulation resistance measured is no lower than 5Ù
CAUTIONCAUTION
IoutIout
90%90%
80%80% 10001000 20002000 30003000 40004000MM
Fig. 1-4 Diagram of Inverter Derating CurveFig. 1-4 Diagram of Inverter Derating Curve
100%100%
DO NOT touch the radiator or charging resistor of the inverter
with hand(s). Otherwise, there is the possibility of getting scalded.
DO NOT proceed direct start-stop operation frequently with a
contactor or any other switch devices in the inverter input side. As
large charging current exists in the main circuit of the inverter,
frequent power-on/off may produce cumulative effect resulting in
heat fatigue of inverter components and great reduction of service
life of the inverter. See the detail in Figure 1-5.
DO NOT touch the radiator or charging resistor of the inverter
with hand(s). Otherwise, there is the possibility of getting scalded.
DO NOT proceed direct start-stop operation frequently with a
contactor or any other switch devices in the inverter input side. As
large charging current exists in the main circuit of the inverter,
frequent power-on/off may produce cumulative effect resulting in
heat fatigue of inverter components and great reduction of service
life of the inverter. See the detail in Figure 1-5.
Chapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety InstructionsChapter 1 Safety Instructions
FORBIDDENFORBIDDEN
INVERTERINVERTER
FORBIDDENFORBIDDEN
FORBIDDENFORBIDDEN
In case abnormalities occur, such as smoke, off odor, strange
sound, DO cut off the power supply immediately, overhaul the
equipment or turn to the agent for help via phone call.
In case abnormalities occur, such as smoke, off odor, strange
sound, DO cut off the power supply immediately, overhaul the
equipment or turn to the agent for help via phone call.
Fig. Fig.
ForbiddenForbidden
MM~~
ON
1.6 Cautions for Disposing1.6 Cautions for Disposing
Exposure may happen when the electrolytic capacitor (ELCC) of the inverter burns. Be careful to cope with it.
The plastic parts on the operator panel will give off toxic gas when getting burned. Be careful to cope with it.
Exposure may happen when the electrolytic capacitor (ELCC) of the inverter burns. Be careful to cope with it.
The plastic parts on the operator panel will give off toxic gas when getting burned. Be careful to cope with it.
Dispose damaged inverter as industrial waste. Dispose damaged inverter as industrial waste.
CAUTIONCAUTION
Chapter 1 Safety InstructionsChapter 1 Safety Instructions
Three-phase AC Power SupplyThree-phase AC Power Supply INVERTERINVERTER
OFF
COMPULSORY
WARNING
2.4 Outside Drawing & Structure2.4 Outside Drawing & Structure
Fig. 2-3 Model A Outside DrawingFig. 2-3 Model A Outside Drawing
Fig. 2-4 Model A Structural RepresentationFig. 2-4 Model A Structural Representation
Chapter 2 Introduction to the ProductChapter 2 Introduction to the Product
This product is guaranteed a high level of quality with strict outgoing inspection,
crushproof and shockproof packaging. But this does not preclude damage to the product
due to heavy collision or strong extrusion. So it is necessary to unpack the inverter upon
arrival and perform these steps:
Check whether there is a deformed or damaged casing; or any shattered component.
Check the specifications label of the inverter and make sure it matches the product part
number you've ordered.
Check whether the items in the packing list are in readiness or not.
If there is any problem with the above-mentioned contents, please contact the supplier or
Ziri Company immediately.
This product is guaranteed a high level of quality with strict outgoing inspection,
crushproof and shockproof packaging. But this does not preclude damage to the product
due to heavy collision or strong extrusion. So it is necessary to unpack the inverter upon
arrival and perform these steps:
Check whether there is a deformed or damaged casing; or any shattered component.
Check the specifications label of the inverter and make sure it matches the product part
number you've ordered.
Check whether the items in the packing list are in readiness or not.
If there is any problem with the above-mentioned contents, please contact the supplier or
Ziri Company immediately.
2.1 Unpacking and Inspection upon Arrival2.1 Unpacking and Inspection upon Arrival
2.2 Diagram of the Model2.2 Diagram of the Model
Fig. 2-1 Inverter Model DiagramFig. 2-1 Inverter Model Diagram
2.3 Specifications Label2.3 Specifications Label
TrademarkTrademarkInverter ModelAdaptive Motor PowerInput Power RatingOutput Power RatingManufacturing Codes
Inverter ModelAdaptive Motor PowerInput Power RatingOutput Power RatingManufacturing Codes
INVERTER
MODEL
POWER
INPUT
OUTPUT
NO
Fig. 2-2 Specifications LabelFig. 2-2 Specifications Label
Inverter ModelInverter Model
Design NumberDesign Number Single PhaseThree PhaseSingle PhaseThree Phase
Motor PowerMotor Power
Chapter II Introduction to the ProductChapter II Introduction to the Product
Type Code Constant Torque
Square Torque
Voltage Class Code
Code Voltage Phase Number
Code
1. Operator Panel 2.Control Panel 3. External Control Terminal 4. Main Circuit Board 5.Power Terminal 6. Casing 7.Fan 8.Installation Hole Site 9.Upper Cover
Chapter 2 Introduction to the ProductChapter 2 Introduction to the Product
Fig. 2-5 Model B Outside DrawingFig. 2-5 Model B Outside Drawing
Fig. 2-6 Model B Structural RepresentationFig. 2-6 Model B Structural Representation
1.Upper Cover 2. Operator Panel 3. Power Terminal 4. External Control Terminal
5. Control Panel 6. Installation Hole Site 7. Casing
1.Upper Cover 2. Operator Panel 3. Power Terminal 4. External Control Terminal
5. Control Panel 6. Installation Hole Site 7. Casing
Fig. 2-7 Model C Outside DrawingFig. 2-7 Model C Outside Drawing
1.Fan 2. Control Panel 3.Cabnet Body 4. Wiring Copper Bar 5.Power Terminal
6. Electrolytic Capacitor (ELCC) 7. Operator Panel 8. Cabinet Door
1.Fan 2. Control Panel 3.Cabnet Body 4. Wiring Copper Bar 5.Power Terminal
6. Electrolytic Capacitor (ELCC) 7. Operator Panel 8. Cabinet Door
Fig. 2-8 Model C Structural RepresentationFig. 2-8 Model C Structural Representation
Chapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the Product
Models and SpecificationsModels and Specifications
Table 2-1 Inverter ModelsTable 2-1 Inverter Models
( )( )G Constant Torque LoadP Fan or Pump Load
(G Constant Torque Load)(P Fan or Pump Load)
Input VoltageInput VoltageInverter ModelsInverter Models
(V) (V)
Rated Output Current A
Adaptive Motor Power ( )
( )G Constant Torque LoadP Fan or Pump Load
(G Constant Torque Load)(P Fan or Pump Load)
InputInputInverter ModelsInverter Models
(V) (V)
Rated Output Current A
Adaptive Motor Power Voltage Voltage
Chapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the Product
-15--15-
2.6 Technical Indications2.6 Technical Indications
Table 2-2 Description Summary for Technical IndicationsTable 2-2 Description Summary for Technical Indications
ItemItem
Inp
ut
Inp
ut
Ou
tpu
tO
utp
ut
Co
ntro
l Fu
nctio
nC
on
trol F
un
ction
Rated Voltage, Rated Voltage,
Allowable Voltage RangeAllowable Voltage Range
Rated VoltageRated Voltage
FrequencyFrequency
Overload CapabilityOverload Capability
Modulation SystemModulation System
Regulating RangeRegulating Range
Frequency AccuracyFrequency Accuracy
Frequency ResolutionFrequency Resolution
Starting TorqueStarting Torque
Torque LiftingTorque Lifting
Slip CompensationSlip Compensation
Acceleration/Deceleration timeAcceleration/Deceleration time
Carrier frequencyCarrier frequency
V/F curveV/F curve
Item DescriptionItem Description
Built-in PIDBuilt-in PID
Input SignalInput Signal
Output signalOutput signal
Dynamic brakingDynamic braking
DC brakingDC brakingO
peratio
n Fu
nctio
nO
peratio
n Fu
nctio
nB
ra
kin
g F
un
ctio
nB
ra
kin
g F
un
ctio
n
Other FunctionOther Function
Protection FunctionProtection Function
ItemItem Item DescriptionItem Description
Co
ntro
l Fu
nctio
nC
on
trol F
un
ction
FrequencyFrequencySingle/Three Phase 220 VAC, Three Phase 380VAC, 50Hz/60Hz
Effective Value of Voltage: 180~230V for Grade 220V; 320~460V for Grade 380V
Unbalance Value of Voltage: <3%; Frequency Fluctuation 5%
Three Phase: 0~ Input Voltage VACThree Phase: 0~ Input Voltage VAC
Model G: Permanent if overload<110%; 1 min if 110%<overload<150%; 2 sec if 150%<overload<180%; instant if overload 200%. Model P: 1 min if overload<120%; 1 sec if 120%<overload<150%; instant if overload 180%.
Magnetic Flux Vector Pulse-Width Modulation (PWM)
Digital Setting Max. Frequency 0.01%Analogue Setting Max. Frequency 0.2%
Digital Setting 0.01Hz; Analogue Setting Max. Frequency 0.1%
100% rated torque at 0.50Hz.
Automatic torque lifting: to lift the torque automatically according to the output current.Hand-operated torque lifting: Range: 1~30%
Setting range: 0~20%. The inverter output frequency can be auto-regulated within this range according to the motor load so as to reduce the speed variation of the motor due to load fluctuation.
0.1~6,000 sec, which can be set in sequence.
1.0 13KHz1.0 13KHz
0 400Hz0 400Hz
1 1001 100
1.linear curve
2.quadratic curve
Automatic energy-saving operation
Auto optimize V/F curve according to load fluctuation to realize energy-saving operation.
Auto Voltage Regulation
When the network voltage changes, it can regulate PWM output automatically to maintain constant voltage.
This can form a convenient closed-loop control system (CLCS), and is applicable to pressure control, flow control and other process control.
Operating instructionoperator panel control, external terminal control and COM control
Frequency setting
panel potentiometer setting, operator panel setting, external terminal up/down setting, analogue voltage signal or external potentiometer setting, analogue current signal setting, analogue nest setting and 485 COM setting.
Forward/Reverse signal, multiple speed signal, failure signal, reset signal and etc.programmable open-collector output impedance, failure signal output
Analogue output terminal
This can realize the output of DC 0~10V signal, frequency, current and other physical quantity.
With an external braking resistor, the maximum braking torque may reach 100%.This can be selected when the motor starts or stops with the action frequency of 0~20Hz action voltage level of 0~20% and actuation time of 0~30 sec., and this value can be set in sequence.
Other functions: Leap frequency, jog function, counter, trace to rotating speed, instant shutdown restarting, frequency upper/lower limitation, acceleration/deceleration mode regulating, frequency meter and voltmeter output, multiple speed/program operation, two-wire/three-wire control, dipolar control, multi-function input terminal selection, failure auto reset and 485 COM.
Protection function: input open-phase protection, over-current protection, overload protection, undervoltage protection, overheating protection and etc.
Chapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the ProductChapter 2 Introduction to the Product
Am
bien
t A
mb
ient
Stru
ctu
reS
tructu
re
LED displayLED display
Matching partsMatching parts
Place to be usedPlace to be used
AltitudeAltitude
Ambient TemperatureAmbient Temperature
HumidityHumidity
Vibration Vibration
Storage TemperatureStorage Temperature
Protective ClassProtective Class
Cooling systemCooling system
InstallationInstallation
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
3.1 Installation3.1.1 Use the inverter in the following environmental conditions:
Altitude: Maximum 1000m above sea level
Ambient Temperature: -10~+45 [Bare Machine: -10~+50 ]
Humidity: 20~90% RH (Non-condensing)
Ambient: Indoor places free from direct exposure to sunlight,
dust, corrosive gas, flammable gas, oil mist, steam, drip and
salt.
Vibration: < 0.5G
3.1.2 Installation Space and DirectionTo get better cooling effect and for the convenience of
maintenance, the inverter shall be installed vertically with
enough space left (refer to Figure 3-1). When two or more
inverters are fixed in the same cabinet, it is recommended to fix
them in parallel and horizontally to reduce heat produced by them
(refer to Figure 3-2). When there is a must to fix them up and down,
please fix an insulating board between them so that the heat
produced by the lower one could not have direct influence on the
upper one (refer to Figure 3-3).
3.1 Installation
Altitude: Maximum 1000m above sea level
Ambient Temperature: -10~+45 [Bare Machine: -10~+50 ]
Humidity: 20~90% RH (Non-condensing)
Ambient: Indoor places free from direct exposure to sunlight,
dust, corrosive gas, flammable gas, oil mist, steam, drip and
salt.
Vibration: < 0.5G
3.1.2 Installation Space and DirectionTo get better cooling effect and for the convenience of
maintenance, the inverter shall be installed vertically with
enough space left (refer to Figure 3-1). When two or more
inverters are fixed in the same cabinet, it is recommended to fix
them in parallel and horizontally to reduce heat produced by them
(refer to Figure 3-2). When there is a must to fix them up and down,
please fix an insulating board between them so that the heat
produced by the lower one could not have direct influence on the
upper one (refer to Figure 3-3).
3.1.1 Use the inverter in the following environmental conditions:
Fig. 3-1 Diagram of Installation Space
Fig. 3-1 Diagram of Installation Space
.Fig 3-2 Diagram of Multi-piece Parallel Installation
Fig. 3-2 Diagram of Multi-piece Parallel Installation
Fig. 3-3 Diagram of Multi-piece Vertical Installation
Fig. 3-3 Diagram of Multi-piece Vertical Installation
Air outletAir outlet >10cm>10cm
> 8cm> 8cmMODE
REV
JOGRUN
FUNC
DATA
STOP
RESET
SHIFT
Hz A V FWD REV
ZVF9-GO150T4ZVF9-GO150T4
15KW 380V 3PH15KW 380V 3PH
CAUTICNCbn l kyfdh j poj jhgffd
WARNING
Read the u ser's manual.Do not connect AC power to output terminals UVW.Do not open the cover while power is applied or
at least 10 minutes after power has been removed.
MODE
REV
JOGRUN
FUNC
DATA
STOP
RESET
SHIFT
MODE
REV
JOGRUN
FUNC
DATA
STOP
RESET
SHIFT
CAUTICNCbn l kyfdh j poj jhgffd
WARNING
Read the u ser's manual.Do not connect AC power to output termiDo not open the cover while power is a
at least 10 minutes after power has been r
CAUTICNCbn l kyfdh j poj jhgffd
WARNING
Read the u ser's manual.Do not connect AC power to output termiDo not open the cover while power is a
at least 10 minutes after power has been r
ZVF9-GO150T4ZVF9-GO150T4
15KW 380V 3PH15KW 380V 3PH
ZVF9-GO150T4ZVF9-GO150T4
15KW 380V 3PH15KW 380V 3PH
ItemItem Item DescriptionItem Description
Real-time display the running state, monitoring parameters, function parameters, diagnostic trouble codes (DTC) and other information of the inverter.
brake assembly, remote operator panel, connecting wire, communication panel
Indoor location free from direct exposure to sunlight, high humidity or dew condensation, high levels of dust, corrosive gas, explosive gas, inflammable gas, oil mist, salt and etc.
Below 1,000M
-10~+45 [Bare Machine:-10~+50 ]
20~90%RH without dew condensation
<0.5G
-20~+60
Ip20
forced air cooling
wall mounted or floor-type actuator
>8cm>8cm
>10cm>10cm air inlet air inlet
Air outletAir outlet
Air outletAir outlet
air inlet air inlet
Air outletAir outlet
Induced spacer
Chapter 2 Introduction to the ProductChapter 2 Introduction to the Product
CAUTION!CAUTION!
Do not install or operate if the inverter is damaged or has parts
missing to prevent injury to personnel or loss of property.
Be sure the main loop terminal should be tightly connected to the
cable. Otherwise, the inverter may be damaged arising from loose
connection.
Be sure the ground terminals of the inverter and the motor must
be reliably and properly grounded. Multi-piece inverter should be
grounded at one shared point.
Do not install or operate if the inverter is damaged or has parts
missing to prevent injury to personnel or loss of property.
Be sure the main loop terminal should be tightly connected to the
cable. Otherwise, the inverter may be damaged arising from loose
connection.
Be sure the ground terminals of the inverter and the motor must
be reliably and properly grounded. Multi-piece inverter should be
grounded at one shared point.
WARNING!WARNING!
3.1.3 Installation Instructions3.1.3 Installation Instructions
Be sure to install a no-fuse circuit breaker or leakage protective circuit breaker in the side of inverter input power supply to prevent expanding of accident due to an inverter problem.
Be sure to install a no-fuse circuit breaker or leakage protective circuit breaker in the side of inverter input power supply to prevent expanding of accident due to an inverter problem.
Install the inverter in a proper place with moderate temperature. The higher the ambient temperature is, the shorter the service life of the inverter is.
Keep any other heat-producing equipment as far away from the inverter as possible. When installing the inverter in an enclosure, maintain the clearance around the inverter and verify the temperature is within the allowable range.
Install the inverter in a proper place with moderate temperature. The higher the ambient temperature is, the shorter the service life of the inverter is.
Keep any other heat-producing equipment as far away from the inverter as possible. When installing the inverter in an enclosure, maintain the clearance around the inverter and verify the temperature is within the allowable range.
3.2 Parts Dismantling and Installation3.2 Parts Dismantling and Installation
3.2.1 Dismantle the upper cover.3.2.1 Dismantle the upper cover. 1 Dismantle the upper cover of the inverter Model A.Put a finger into the notch of the lower part of the inverter (as shown in Figure 3-4 where the arrow points), stretch upward for 30~50mm (as shown in Figure 3-5), then push forward to open the upper cover of the inverter.
1 Dismantle the upper cover of the inverter Model A.Put a finger into the notch of the lower part of the inverter (as shown in Figure 3-4 where the arrow points), stretch upward for 30~50mm (as shown in Figure 3-5), then push forward to open the upper cover of the inverter.
2 Dismantle the upper cover of the inverter Model B.
Unscrew two screws of the lower part of the inverter (as shown in Figure 3-6 where the
arrow points), stretch upward for 30~70mm (as shown in Figure 3-7), then push
forward to open the upper cover of the inverter.
2 Dismantle the upper cover of the inverter Model B.
Unscrew two screws of the lower part of the inverter (as shown in Figure 3-6 where the
arrow points), stretch upward for 30~70mm (as shown in Figure 3-7), then push
forward to open the upper cover of the inverter.
Fig. 3-4 Diagram of dismantling the upper cover of the inverter Model A
Fig. 3-4 Diagram of dismantling the upper cover of the inverter Model A
Fig. 3-5 Diagram of dismantling the upper cover of the inverter Model A
Fig. 3-5 Diagram of dismantling the upper cover of the inverter Model A
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
COMPULSORY!
Fig. 3-6 Diagram of dismantling the upper cover of the inverter Model B
Fig. 3-7 Diagram of dismantling the upper cover of the inverter Model B
3.2.2 Installation of the remote-controlled operator panel and connecting wire
1 Installation of the operator panel and connecting wire of the inverter Model A
Step 1. Open the upper cover of the inverter (as shown in Figure 3-4 and Figure 3-5).
Step 2. Button up with hand at the chink of the upper part of operator panel and remove
the operator panel (as shown in Figure 3-8).
3.2.2 Installation of the remote-controlled operator panel and connecting wire
1 Installation of the operator panel and connecting wire of the inverter Model A
Step 1. Open the upper cover of the inverter (as shown in Figure 3-4 and Figure 3-5).
Step 2. Button up with hand at the chink of the upper part of operator panel and remove
the operator panel (as shown in Figure 3-8).
Fig. 3-8 Mounting Diagram of the operator panel and connecting wire of the inverter Model AStep 3. Fix the jack panel provided in the optional components in the installation position of operator panel (as shown in Figure 3-9).
Fig. 3-8 Mounting Diagram of the operator panel and connecting wire of the inverter Model AStep 3. Fix the jack panel provided in the optional components in the installation position of operator panel (as shown in Figure 3-9).
Fig. 3-9 Mounting Diagram of the operator panel and connecting wire of the inverter Model AFig. 3-9 Mounting Diagram of the operator panel and connecting wire of the inverter Model A
Fig. 3-11 Mounting Diagram of the operator panel and connecting wire of the inverter Model AFig. 3-11 Mounting Diagram of the operator panel and connecting wire of the inverter Model A
Step 4. Install the dismantled upper cover in the previous location, plug the ground end of connecting wire into the slot of jack panel (as shown in Figure 3-10).Step 4. Install the dismantled upper cover in the previous location, plug the ground end of connecting wire into the slot of jack panel (as shown in Figure 3-10).
Fig. 3-10 Mounting Diagram of the operator panel and connecting wire of the inverter Model AFig. 3-10 Mounting Diagram of the operator panel and connecting wire of the inverter Model A
Step 5. Put the dismantled operator panel into the installation frame provided in the optional components, fix and fasten it. Plug the other end of connecting wire into the jack panel slot, and then plug the slot into operator panel (as shown in Figure 3-11).
Step 5. Put the dismantled operator panel into the installation frame provided in the optional components, fix and fasten it. Plug the other end of connecting wire into the jack panel slot, and then plug the slot into operator panel (as shown in Figure 3-11).
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Installation of the operator panel and connecting wire of the inverter Model BInstallation of the operator panel and connecting wire of the inverter Model B
Step 1. Open the upper cover of the inverter (as shown in Figure 3-6 and Figure 3-7).Step 2. Press the direction that the arrow points to strenuously and push outward to remove the operator panel (as shown in Figure 3-12).
Step 1. Open the upper cover of the inverter (as shown in Figure 3-6 and Figure 3-7).Step 2. Press the direction that the arrow points to strenuously and push outward to remove the operator panel (as shown in Figure 3-12).
Fig. 3-12 Mounting Diagram of the operator panel and connecting wire of the inverter Model BFig. 3-12 Mounting Diagram of the operator panel and connecting wire of the inverter Model B
Step 3. Plug the connecting wires of the control panel and operator panel into the jack panel provided in the optional components. Put on the upper cover of the inverter, and then fix the jack panel in the installing location of operator panel (as shown in Figure 3-13).
Step 3. Plug the connecting wires of the control panel and operator panel into the jack panel provided in the optional components. Put on the upper cover of the inverter, and then fix the jack panel in the installing location of operator panel (as shown in Figure 3-13).
Fig. 3-13 Mounting Diagram of the operator panel and connecting wire of the inverter Model B
Fig. 3-13 Mounting Diagram of the operator panel and connecting wire of the inverter Model B
Fig. 3-14 Mounting Diagram of the operator panel and connecting wire of the inverter Model BFig. 3-14 Mounting Diagram of the operator panel and connecting wire of the inverter Model B
Fig. 3-15 Mounting Diagram of the operator panel and connecting wire of the inverter Model BFig. 3-15 Mounting Diagram of the operator panel and connecting wire of the inverter Model B
lug the grounding end of connecting wire into the slot of jack panel (as shown in Figure 3-14).
lug the grounding end of connecting wire into the slot of jack panel (as shown in Figure 3-14).
Step 5. Fix and fasten the dismantled operator panel, and put the other end of connecting wire into the socket of operator panel (as shown in Figure 3-15).Step 5. Fix and fasten the dismantled operator panel, and put the other end of connecting wire into the socket of operator panel (as shown in Figure 3-15).
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
3.3 Inverter Wiring3.3 Inverter Wiring
3.3.1 Basic System Description on Inverter Wiring3.3.1 Basic System Description on Inverter Wiring
24 Power Supply Output Port
485 COM Port
Analog Signal Output
M
Analog voltage signal input
Analog current signal input
mA
MCCB
Fig. 3-16 Basic System Description on WiringFig. 3-16 Basic System Description on Wiring
Applicable to ModelApplicable to Model
Applicable to Model 7 45ZVF9-G03 0T4 G2800T4 ZVF9-P0 0T4 P3150T4Applicable to Model ZVF9-G0370T4 G2800T4 ZVF9-P0450T4 P3150T4
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Braking Unit Braking Resistance
Three-phase AC I n p u t P o w e r Supply
Forward RunningReverse Running
Terminal X1Terminal X2Terminal X3Terminal X4Terminal X5Terminal X6
Public Terminal
Fig. 3-17 Basic System Description on WiringFig. 3-17 Basic System Description on Wiring
Open collector Output
MCCB
M
Reactor
Error Relay OutputNormal, TA-TB CloseError, TA-TC Close
Three-phase AC I n p u t P o w e r Supply
Forward RunningReverse Running
Terminal X1Terminal X2Terminal X3Terminal X4Terminal X5Terminal X6
Public Terminal
Analog Signal Output
24 Power Supply Output Port
485 COM Port
Analog voltage signal input
Analog current signal input
mA
Braking Unit
Cautions for WiringCautions for Wiring
Verify the rated input voltage of the inverter is matched with
AC power supply. Otherwise, there is the possibility of damage to
the inverter.
Install in order and only operate wiring after finishing main
parts installation. Otherwise, there is an electric shock or
damage to the inverter.
Do not perform over-voltage withstand to the inverter, for this
had been done properly before EX-factory.
Be sure to install a non-fuse circuit breaker in the input power
supply side of the inverter toprevent expanding of accident
due to an inverter problem, which may cause damage to the
distribution equipment or lead to fire.
Be sure to connect the ground terminal and the motor casing to
the ground wire which must be copper core. The diameter of the
wire should conform to the relevant national standard. The
ground resistance should be less than 10
Verify the rated input voltage of the inverter is matched with
AC power supply. Otherwise, there is the possibility of damage to
the inverter.
Install in order and only operate wiring after finishing main
parts installation. Otherwise, there is an electric shock or
damage to the inverter.
Do not perform over-voltage withstand to the inverter, for this
had been done properly before EX-factory.
Be sure to install a non-fuse circuit breaker in the input power
supply side of the inverter to prevent expanding of accident
due to an inverter problem, which may cause damage to the
distribution equipment or lead to fire.
Be sure to connect the ground terminal and the motor casing to
the ground wire which must be copper core. The diameter of the
wire should conform to the relevant national standard. The
ground resistance should be less than 10
Wait at least 10 minutes after power OFF before opening the
upper cover of the inverter.
Verify the charge lamp indicator is OFF before proceeding the
work, and be sure that the voltage value of main loop terminal
P and DC is less than 36VDC.
The internal wiring of the inverter should be operated only by
authorized qualified personnel.
Wait at least 10 minutes after power OFF before opening the
upper cover of the inverter.
Verify the charge lamp indicator is OFF before proceeding the
work, and be sure that the voltage value of main loop terminal
P and DC is less than 36VDC.
The internal wiring of the inverter should be operated only by
authorized qualified personnel.
When the open-ended output terminal of the collector connects
to the inductive load, i.e., the relay coil, do insert a diode at each
end of the load in parallel.
The control wire in the inverter or the control cabinet should be at
least 100mm away from the power cable. DO NOT put them in the
same metallic channel. If the signal wire and the power cable
intersect, the interference will be smallest if they intersect at an
angle of 90o. The control wire must adopt STP (shielded twisted
pair wire); the shielded layer must connect to the terminal GND;
and the power wire is recommended to use metallic shielded cable.
When the open-ended output terminal of the collector connects
to the inductive load, i.e., the relay coil, do insert a diode at each
end of the load in parallel.
The control wire in the inverter or the control cabinet should be at
least 100mm away from the power cable. DO NOT put them in the
same metallic channel. If the signal wire and the power cable
intersect, the interference will be smallest if they intersect at an
angle of 90o. The control wire must adopt STP (shielded twisted
pair wire); the shielded layer must connect to the terminal GND;
and the power wire is recommended to use metallic shielded cable.
The unavoidable strong electromagnetic interference of the
inverter may have bad influence on all the electrical equipment
and meters in the same environment. To reduce interference, the
output cable of the inverter can be inserted in the metal pipe
connecting to the ground or in the metallic shielded cable, and
connect the metallic shielded layer to the ground. In addition, a
magnetic loop put on the output cable is also effective to reduce
interference.
The unavoidable strong electromagnetic interference of the
inverter may have bad influence on all the electrical equipment
and meters in the same environment. To reduce interference, the
output cable of the inverter can be inserted in the metal pipe
connecting to the ground or in the metallic shielded cable, and
connect the metallic shielded layer to the ground. In addition, a
magnetic loop put on the output cable is also effective to reduce
interference.
DO NOT connect AC power supply to the output terminals
marked,U,V,W ,Otherwise, there will be damage to the inverter.
DO NOT connect control terminals(except terminals marked
TA , TB and TC ) to AC 220V power supply, which
may cause damage to the inverter.
DO NOT connect AC power supply to the output terminals
marked,U,V,W ,Otherwise, there will be damage to the inverter.
DO NOT connect control terminals(except terminals marked
TA , TB and TC ) to AC 220V power supply, which
may cause damage to the inverter.
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Hazard!
WARNING!
FORBIDDEN
TIPs
TIPs
connect to ground
3.3.3 Instruction on Main Circuit Terminals3.3.3 Instruction on Main Circuit Terminals
The main circuit terminals are shown as in Figure 3-18~3-22.The main circuit terminals are shown as in Figure 3-18~3-22.
Fig. 3-19 Diagram of Main Circuit Terminals (2) Fig. 3-19 Diagram of Main Circuit Terminals (2)
Applicable to ModelApplicable to Model
Applicable to Model P 15 P 110
ZVF9-G0007T2 G0055T2 ZVF9-G0007T4 G0075T4ZVF9- 00 T4 0 T4
Applicable to Model ZVF9-G0007T2 G0055T2 ZVF9-G0007T4 G0075T4 ZVF9-P0015T4 P0110T4
braking resistance
braking unit
Fig. 3-20 Diagram of Main Circuit Terminals (3) Fig. 3-20 Diagram of Main Circuit Terminals (3)
Applicable to ModelApplicable to Model
Fig. 3-21 Diagram of Main Circuit Terminals (4) Fig. 3-21 Diagram of Main Circuit Terminals (4)
Applicable to ModelApplicable to Model
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
single phase 220V power supply input
connect to braking resistance
connect to three-phase AC motor
connect to ground
connect to braking resistance
connect to three-phase AC motor
three-phase 380V (or three-phase 220V) power supply input
connect to ground
three-phase 380V power supply input
connect to three-phase AC motor
braking unitthree-phase 380V power supply input
connect to three-phase AC motor
connect to ground
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Fig. 3-22 Diagram of Main Circuit Terminals (5) Fig. 3-22 Diagram of Main Circuit Terminals (5)
Fig. 3-23 Diagram of Main Circuit Terminals (6) Fig. 3-23 Diagram of Main Circuit Terminals (6)
Applicable to Model 1850 2000ZVF9-G1320T4 G T4 ZVF9-P1600T4 P T4Applicable to Model ZVF9-G1320T4 G1850T4 ZVF9-P1600T4 P2000T4
Applicable to Model 200 2800 22 3150ZVF9-G 0T4 G T4 ZVF9-P 00T4 P T4Applicable to Model ZVF9-G2000T4 G2800T4 ZVF9-P2200T4 P3150T4
Terminal SignalsTerminal Signals Function DescriptionFunction Description
2 Function Descriptionof Main Circuit Terminals 2 Function Description of Main Circuit Terminals
Table 3-1 Main Loop Terminals Function DescriptionTable 3-1 Main Loop Terminals Function Description
TipsTips
The three-phase input power supply terminals (R, S and T) do not differ on phase sequence and can be connected arbitrarily.
If the motor counter rotates (reverses) when the output terminals U, V and W connect to three-phase motor, just exchange two phases of U, V and W arbitrarily.
A braking unit is required to be installed inside the inverter under 15KW. If an external braking resistance is required, just connect to the external braking resistance between terminal P and terminal DB.
An inverter higher than 18.5KW has no internal braking unit, so it has no DB terminal. If a braking torque is needed, please connect to the external braking units including braking unit and braking resistance between P and DC-.
ZVF9-G1320T4/P1600T4 or even updated model is matched with DC reactor. If an inverter has no internal DC reactor, just fix a DC reactor between P and DC+. When performing this step, it is required to remove the short-circuit ring, then connect to the reactor (applicable to the inverter of 30KW or higher power).
The three-phase input power supply terminals (R, S and T) do not differ on phase sequence and can be connected arbitrarily.
If the motor counter rotates (reverses) when the output terminals U, V and W connect to three-phase motor, just exchange two phases of U, V and W arbitrarily.
A braking unit is required to be installed inside the inverter under 15KW. If an external braking resistance is required, just connect to the external braking resistance between terminal P and terminal DB.
An inverter higher than 18.5KW has no internal braking unit, so it has no DB terminal. If a braking torque is needed, please connect to the external braking units including braking unit and braking resistance between P and DC-.
ZVF9-G1320T4/P1600T4 or even updated model is matched with DC reactor. If an inverter has no internal DC reactor, just fix a DC reactor between P and DC+. When performing this step, it is required to remove the short-circuit ring, then connect to the reactor (applicable to the inverter of 30KW or higher power).
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Three-phase 380V i n p u t p o w e r supply
Three-phase 380V i n p u t p o w e r supply
Connect to braking unit
Connect to braking unit
Connect to three-phase AC motor
Connect to three-phase AC motor
Connect to ground
Connect to ground
Power supply input terminals connecting to three-phase 380V or 220V AC input power supplyPower supply input terminals connecting to single phase 220V AC input power supply
Inverter output terminals connecting to three-phase AC motor
External braking resistance terminals connecting to both ends of external braking resistance
External braking unit terminals; terminal P connects to the positive end of the braking unit and DC- connects to the negative end.
Ground terminal or ground wire
External braking Reactor terminals
3.3.4 Description on Control Circuit Terminals3.3.4 Description on Control Circuit Terminals
1 Control circuit terminals shown in Figure 3-23 and 3-241 Control circuit terminals shown in Figure 3-23 and 3-24
Fig. 3-24 Control Circuit Terminals (2)Fig. 3-24 Control Circuit Terminals (2)
Fig. 3-23 Control Circuit Terminals (1)Fig. 3-23 Control Circuit Terminals (1)
Terminal SymbolsTerminal Symbols Function DescriptionFunction Description Electrical SpecificationsElectrical SpecificationsTypesTypes
3.3.4 Description on Control Circuit Terminals3.3.4 Description on Control Circuit Terminals
Table 3-2 Function Description of Control Circuit TerminalsTable 3-2 Function Description of Control Circuit Terminals
Public PortPublic Port
Running Control Terminal
Running Control Terminal
Multi-function Input Terminal
Multi-function Input Terminal
Multi-function Output Terminal
Multi-function Output Terminal
Numeral Signal Public TerminalNumeral Signal Public Terminal
Forwarding when FWD-COM shortcuts, decelerating and stopping when FWD-COM is open.
Forwarding when FWD-COM shortcuts, decelerating and stopping when FWD-COM is open.
Reversing when REV-COM shortcuts, decelerating and stopping when REV-COM is open.
Reversing when REV-COM shortcuts, decelerating and stopping when REV-COM is open.
Valid only when there is a short-circuit between Xn (n=1, 2, 3, 4, 5, 6) and COM. The functions can be set by the parameter F111~F116 separately.
Valid only when there is a short-circuit between Xn (n=1, 2, 3, 4, 5, 6) and COM. The functions can be set by the parameter F111~F116 separately.
Multi-function open-collector output is defined as on-off output terminal, whose function is set by the parameter F117~F118 with reference of COM.
Multi-function open-collector output is defined as on-off output terminal, whose function is set by the parameter F117~F118 with reference of COM.
INPUT, 0~24power level, low level valid, 5mA
INPUT, 0~24power level, low level valid, 5mA
OUTPUT, Maximum Current Load OUTPUT, Maximum Current Load
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
INPUT, 0~24power level, low level valid, 5mA
INPUT, 0~24power level, low level valid, 5mA
3.4 Wiring Diagram of Inverter System3.4 Wiring Diagram of Inverter System
Fig. 4-25 Connection between the Inverter and Optional AccessoriesFig. 4-25 Connection between the Inverter and Optional Accessories
No-fuse circuit breaker MCCBNo-fuse circuit breaker MCCB
Magnetic Contactor KMMagnetic Contactor KM
Input AC Reactor ACLInput AC Reactor ACL
Input EMI FilterInput EMI Filter
DC Reactor DCLDC Reactor DCL External Braking
ResistanceExternal Braking Resistance
External Braking UnitsExternal Braking Units
Output EMI FilterOutput EMI Filter
Output AC Reactor ACLOutput AC Reactor ACL
INVERTERINVERTER
Analog Input Terminal
Analog Input Terminal
Analog Output Terminal
Analog Output Terminal
Power Supply Interface
Power Supply Interface
Failure Output Terminal
Failure Output Terminal
External analog preset power supply connecting to potentiometer together with terminal GND and V. The frequency can be set as required.
External analog preset power supply connecting to potentiometer together with terminal GND and V. The frequency can be set as required.
Analog voltage signal input, with reference of GND.
Analog voltage signal input, with reference of GND.
Analog current signal input, with reference of GND
Analog current signal input, with reference of GND
Analog voltage output connecting to voltmeter or frequency meter with corresponding output ranging from 0 to the maximum frequency, and reference of GND.
Analog voltage output connecting to voltmeter or frequency meter with corresponding output ranging from 0 to the maximum frequency, and reference of GND.
24VDC Power Supply Output (Control Power Supply)24VDC Power Supply Output (Control Power Supply)
Failure relay contact output used to detect the protection function of the inverter. When the inverter is normal, TA-TB turns on and TA-TC turns off; when the inverter is failure, TA-TB turns on and TA-TC turns off.
Failure relay contact output used to detect the protection function of the inverter. When the inverter is normal, TA-TB turns on and TA-TC turns off; when the inverter is failure, TA-TB turns on and TA-TC turns off.
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Terminal SymbolsTerminal Symbols Function DescriptionFunction Description Electrical SpecificationsElectrical SpecificationsTypesTypes
Public PortPublic Port
Table 3-2 Function Description of Control Circuit TerminalsTable 3-2 Function Description of Control Circuit Terminals
The circuit breaker has the function of over-current protection,
which can avoid extension of external equipment failure. Do pay
attention to the capacity of circuit breaker when installing.
Refer to Table 3-3 to select the circuit breaker.
The magnetic contactor is used to disconnect from the main
power supply in case of inverter failure, and prevent restarting
after power-off or inverter failure.
The input AC reactor can reduce influence arising from
unbalance of three-phase AC power supply, improve the power
factor of the inverter input side and reduce damage to the inverter
when it is connected to large capacity motor which may result in
damage to the rectifier circuit. It is necessary to configure an AC
reactor when any of the following occurred:
The power supply unbalance exceeds 3%.
The power capacity is 500KVA at least and it is 10 times higher
than the inverter capacity.
The power factor is used to compensate the connection or
disconnection of the capacity, and sudden change of network
voltage caused by other reasons.
It is recommended to install a reactor with derating voltage of 3%.
The input and output EMI filters are used to minimize the
magnetic or radio frequency interference (RFI) produced by the
network or the inverter.
The braking units are used to consume the energy fed back by
some heavy potential energy or inertia load to the inverter, so as to
avoid inverter tripping arising from over-tension pumping
voltage while giving a quick shutdown to the inverter.
The output AC reactor can filter out with effect the higher
harmonic components in the inverter output current and reduce the
electromagnetic interference (EMI) due to ultraharmonics. Also, it
can improve current waveform, decrease noise and temperature
rise of a running motor and enhance the stability of motor running.
To avoid influence of leakage current due to distributed capacity of
the cable, it is necessary to install an output AC reactor if the motor
cable is longer.
The circuit breaker has the function of over-current protection,
which can avoid extension of external equipment failure. Do pay
attention to the capacity of circuit breaker when installing.
Refer to Table 3-3 to select the circuit breaker.
The magnetic contactor is used to disconnect from the main
power supply in case of inverter failure, and prevent restarting
after power-off or inverter failure.
The input AC reactor can reduce influence arising from
unbalance of three-phase AC power supply, improve the power
factor of the inverter input side and reduce damage to the inverter
when it is connected to large capacity motor which may result in
damage to the rectifier circuit. It is necessary to configure an AC
reactor when any of the following occurred:
The power supply unbalance exceeds 3%.
The power capacity is 500KVA at least and it is 10 times higher
than the inverter capacity.
The power factor is used to compensate the connection or
disconnection of the capacity, and sudden change of network
voltage caused by other reasons.
It is recommended to install a reactor with derating voltage of 3%.
The input and output EMI filters are used to minimize the
magnetic or radio frequency interference (RFI) produced by the
network or the inverter.
The braking units are used to consume the energy fed back by
some heavy potential energy or inertia load to the inverter, so as to
avoid inverter tripping arising from over-tension pumping
voltage while giving a quick shutdown to the inverter.
The output AC reactor can filter out with effect the higher
harmonic components in the inverter output current and reduce the
electromagnetic interference (EMI) due to ultraharmonics. Also, it
can improve current waveform, decrease noise and temperature
rise of a running motor and enhance the stability of motor running.
To avoid influence of leakage current due to distributed capacity of
the cable, it is necessary to install an output AC reactor if the motor
cable is longer.
Table 3-3 Capacity of Break Switch & Section Area of WireTable 3-3 Capacity of Break Switch & Section Area of Wire
Inverter ModelsInverter Models Break Switch (A)Break Switch (A)
2Main Circuit mm2Main Circuit mm
Input WireInput Wire Output WireOutput Wire
Control Wire 2mm
Control Wire mm
2
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
TipsTips
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
4.1 Operator panel and Description4.1 Operator panel and Description
The inverter ZVF9 series has two operator panels, with potentiometer or without
potentiometer. The standard model does not have a potentiometer before EX-factory. If a
user needs an inverter with a potentiometer, he should tell the manufacturer in advance.
The inverter ZVF9 series has two operator panels, with potentiometer or without
potentiometer. The standard model does not have a potentiometer before EX-factory. If a
user needs an inverter with a potentiometer, he should tell the manufacturer in advance.
1.1Operator Panel Outlay1.1Operator Panel Outlay
Fig. 4-1 Diagram of ZR01 Operator PanelApplicable to Model ZVF9-G0007T2/S2 G0037T2/S2 ZVF9-G0007T4 G0055T4
ZVF9-P0015T4 P0075T4
Fig. 4-1 Diagram of ZR01 Operator PanelApplicable to Model ZVF9-G0007T2/S2 G0037T2/S2 ZVF9-G0007T4 G0055T4
ZVF9-P0015T4 P0075T4
STOP/RESET Key
ENTER Key
MODE Key
UP/DW Key
RUN Key
JOG/REV Key
Panel Potentiometer
Chapter 3 Inverter Installation and WiringChapter 3 Inverter Installation and Wiring
Inverter ModelsInverter Models Break Switch (A)Break Switch (A)
2Main Circuit mm2Main Circuit mm
Input WireInput Wire Output WireOutput Wire
Control Wire 2
mmControl Wire
mm2
Table 3-3 Capacity of Break Switch & Section Area of WireTable 3-3 Capacity of Break Switch & Section Area of Wire
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
LED display area, display the running status.
LED display area, display f r e q u e n c y , c u r r e n t , parameters, error and etc.
Shift/Monitoring key
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
Fig. 4-2 Diagram of ZR02 Operator PanelApplicable to Model ZVF9-G0075T4 G280T4 ZVF9-P0110T4 P3150T4
ZVF9-G0055T2 G0220T2
Fig. 4-2 Diagram of ZR02 Operator PanelApplicable to Model ZVF9-G0075T4 G280T4 ZVF9-P0110T4 P3150T4
ZVF9-G0055T2 G0220T2
4.1.2 Function Description on Key4.1.2 Function Description on Key
Run key. When the operating instruction is to select operator panel
control (F010=0), press this key and the inverter begins to run.
Run key. When the operating instruction is to select operator panel
control (F010=0), press this key and the inverter begins to run.
Stop/Reset key. When the operating instruction is to select operator panel control (F010=0), the inverter is in normal running state. Press this key to stop running. When the inverter is in the state of failure alarming, press this key to solve failure and return to normal state.
Stop/Reset key. When the operating instruction is to select operator panel control (F010=0), the inverter is in normal running state. Press this key to stop running. When the inverter is in the state of failure alarming, press this key to solve failure and return to normal state.
Mode shifting key. Press this key to realize mode switching from monitoring parameter to function parameter.Mode shifting key. Press this key to realize mode switching from monitoring parameter to function parameter.
Enter/Store key. Press this key to confirm current state of the inverter or store current parameter value.Enter/Store key. Press this key to confirm current state of the inverter or store current parameter value.
Jog/Reverse key. Press this key to realize jog or reserve function, and decide jog or reverse function by selecting the parameter F039. The factory default setting is jog function.
Jog/Reverse key. Press this key to realize jog or reserve function, and decide jog or reverse function by selecting the parameter F039. The factory default setting is jog function.
Shift/Monitoring key. When a data needs modifying, press this key to select the modifier bit of data. In the status of monitoring, press this key to display the status parameter.
Shift/Monitoring key. When a data needs modifying, press this key to select the modifier bit of data. In the status of monitoring, press this key to display the status parameter.
Increase key: Press this key, the data or parameter code will go up. Press it still, the modifying speed upward will rise.Increase key: Press this key, the data or parameter code will go up. Press it still, the modifying speed upward will rise.
Decrease key. Press this key, the data or parameter code will go down. Press it still, the modifying speed upward will fall.Decrease key. Press this key, the data or parameter code will go down. Press it still, the modifying speed upward will fall.
STOP/RESET Key
ENTER Key
MODE Key
UP/DW Key
RUN Key
JOG/REV Key
Shift/Monitoring key
Panel Potentiometer
LED display area, display the running status.
LED display area, display f r e q u e n c y , c u r r e n t , parameters, error and etc.
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
TipsTips
In any event, the operator panel will automatically return to the
Monitoring Mode if there is no key entry in 2 continuous minutes.
In the mode of monitoring, the frequency value will be modified
by pressing / on the operator panel when setting F009=0.
In any event, the operator panel will automatically return to the
Monitoring Mode if there is no key entry in 2 continuous minutes.
In the mode of monitoring, the frequency value will be modified
by pressing / on the operator panel when setting F009=0.
3.The correspondence between display symbols of the parameter Fd13 and
external input terminal status in the monitoring mode is shown below:
3.The correspondence between display symbols of the parameter Fd13 and
external input terminal status in the monitoring mode is shown below:
Fig. 4-3 Relationship between input terminal status and display symbols in monitoring modeFig. 4-3 Relationship between input terminal status and display symbols in monitoring mode
Terminal turns ON, valid input of terminal
Terminal turns OFF, invalid input of terminal
Terminal turns ON, valid input of terminal
Terminal turns OFF, invalid input of terminal
Display StatusDisplay Status
4.1.3 Function Description on Operator Panel Indicator Lights4.1.3 Function Description on Operator Panel Indicator Lights
Table 4-1 LED Status DescriptionTable 4-1 LED Status Description
Function DescriptionFunction Description
4.1.4 Working mode and display status of the function keyboard4.1.4 Working mode and display status of the function keyboard
1 Mode of Monitoring State1 Mode of Monitoring State
2 Mode of Function Status 2 Mode of Function Status
Repress MODE key, the inverter will enter the mode of function status (LED displays FRepress MODE key, the inverter will enter the mode of function status (LED displays F
3.Power On/Off Display 3.Power On/Off Display
The LED displays P.oFF when the inverter is just powered on or powered off properly. The LED displays P.oFF when the inverter is just powered on or powered off properly.
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
When this indicator light is ON, LED displays frequency data.
When this indicator light is ON, LED displays current data.
When this indicator light is ON, LED displays voltage data.
When this indicator light is ON, the inverter is in the state of forward running.
When this indicator light is ON, the inverter is in the state of reverse running.
When all of the above 5 light is ON, the inverter is in the state of alarming.
Press key, the inverter enters into monitoring state mode (LED displays Fd ). Under this mode, press / to decide what to be monitored (i.e., a running parameter or failure record).
MODE MODE T
ermin
al Statu
sT
ermin
al Statu
s
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
Term
inal S
tatus
RFVRFVFWD
Modification of monitoring status parameter (change the motor
rotating speed from Fd00 to Fd04).
Modification of monitoring status parameter (change the motor
rotating speed from Fd00 to Fd04).
PressPress
Initiating mode before operationInitiating mode before operation
4.1.5 Use of Operator Panel4.1.5 Use of Operator Panel
Parameter Initiating Parameter Initiating
PressPressContinuously
PressPress
Enter monitoring status.
Set the monitoring status to 4 ( m o t o r r o t a t i n g s p e e d ) .
Confirm the monitoring status and display the motor rotating speed.
Initiating mode before operationInitiating mode before operation
Enter monitoring status.
PressPress
RepressRepress
PressPressContinuously
PressPressContinuously
PressPress
PressPress
Enter the function parameter mode.
Set the function code to jog frequency.
Enter the status of jog function parameter setting.
Set the jog frequency to 20.00Hz.
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
Exit the status of jog frequency parameter setting and save the data.
Return to monitoring mode.
PressPress
PressPress
RepressRepress
PressPressContinuously
PressPress
PressPress
PressPress
PressPress
DescriptionLED DisplayOperation StepsOrder
DescriptionLED DisplayOperation StepsOrder
DescriptionLED DisplayOperation StepsOrder
DescriptionLED DisplayOperation StepsOrder
PressPress
RepressRepress
PressPress Twice
PressPress
PressPress Twice
PressPress
PressPress
Initiating mode before operation
Enter monitoring status.
Enter the function parameter mode.
Initiating mode before operation
Enter monitoring status.
Enter the function parameter mode.
Set the unit position of the function code to 9.
Set the unit position of the function code to 2.
Enter the status of parameter value setting of the frequency set mode.
Set the parameter value of the frequency set mode to 0.
Exit the status of parameter value setting and save the data.
Return to monitoring mode.
Enter the status of function parameter value setting of parameter initializing.
Set the parameter value to 2, which means the initialization of parameter value.Parameter initializing finished and return to the status of function codes.
Return to monitoring mode.
1st diagnostic trouble codes1st diagnostic trouble codes
Acceleration running
over current
Deceleration running
over current
Steady-speed running
over current
Acceleration running
over voltage
Deceleration running
over voltage
Steady running over
voltage
Over voltage when
power off
Under voltage of running
Input side open-phase
Power module failure
Radiator over heat
Inverter overload
Motor overload
external equipment
failure
Remain
Current detection
error
Keyboard
communication failure
COM error
Remain
Acceleration running
over current
Deceleration running
over current
Steady-speed running
over current
Acceleration running
over voltage
Deceleration running
over voltage
Steady running over
voltage
Over voltage when
power off
Under voltage of running
Input side open-phase
Power module failure
Radiator over heat
Inverter overload
Motor overload
external equipment
failure
Remain
Current detection
error
Keyboard
communication failure
COM error
Remain
3rd diagnostic trouble codes
3rd diagnostic trouble codes
4th diagnostic trouble codes4th diagnostic trouble codes
DC bus bar voltage of the latest failure
Output current of the lasted failure
Output frequency of the lasted failure
Total running time of the lasted failure
Module temperature of the lasted failure
DC bus bar voltage of the latest failure
Output current of the lasted failure
Output frequency of the lasted failure
Total running time of the lasted failure
Module temperature of the lasted failure
4.2 Monitoring Parameter Display4.2 Monitoring Parameter Display
Output frequency
Set frequency
Output current
Output voltage
Motor rotation speed
Running linear speed
Set linear speed
DC bus bar voltage
Power module thermometer
PID set value
PID feedback value
Counter value
Total time of current running
Enter terminal status parameter
Output frequency
Set frequency
Output current
Output voltage
Motor rotation speed
Running linear speed
Set linear speed
DC bus bar voltage
Power module thermometer
PID set value
PID feedback value
Counter value
Total time of current running
Enter terminal status parameter
MO
NIT
OR
ING
DIS
PL
AY
PA
RA
ME
TE
RS
CATEGORYDISPLAY CODE
NAME UNIT
Table 4-2 Monitoring Parameter LED Display ListTable 4-2 Monitoring Parameter LED Display List
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
CATEGORYDISPLAY CODE
NAME UNIT
MO
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OR
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DIS
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PA
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TE
RS
Chapter 5 Operation of InverterChapter 5 Operation of Inverter
Chapter 5 Operation of InverterChapter 5 Operation of Inverter
5.1 Trial Operation5.1 Trial Operation
5.1.1 Safety Instruction on Trial Operation 5.1.1 Safety Instruction on Trial Operation
5.1.2 Check before trial operation.5.1.2 Check before trial operation.The following steps should be inspected and confirmed before the trial operation
of the inverter:Be sure that the application ambient and installation for the inverter is in
accordance with the requirements specified in Clause 3.1.Be sure that the main circuit is correctly wired. The input power supply of the
inverter must be connected to the terminal R, S and T. The output terminal U, V and W must be connected to the motor.
Be sure that the ground terminal is reliably and properly grounded.Be sure all the switches and terminals are in proper state of off or shutdown.Be sure there is no short cutting or short to ground of all the terminals and
electrified parts.Be sure all the terminals, connectors and screws are tightly fastened.Be sure the motor has no other loads.
The following steps should be inspected and confirmed before the trial operation of the inverter:
Be sure that the application ambient and installation for the inverter is in accordance with the requirements specified in Clause 3.1.
Be sure that the main circuit is correctly wired. The input power supply of the inverter must be connected to the terminal R, S and T. The output terminal U, V and W must be connected to the motor.
Be sure that the ground terminal is reliably and properly grounded.Be sure all the switches and terminals are in proper state of off or shutdown.Be sure there is no short cutting or short to ground of all the terminals and
electrified parts.Be sure all the terminals, connectors and screws are tightly fastened.Be sure the motor has no other loads.
An inverter stored for half a year or longer must be given powerup test before use, so that the main circuit filtering capacity of the inverter could be recovered. Do raise the voltage gradually by using a voltage regulator to some rated value before it is recharged. Generally, the recharging period lasts 1~2 hours. Otherwise, there is the danger of electric shock or exposure.
An inverter stored for half a year or longer must be given powerup test before use, so that the main circuit filtering capacity of the inverter could be recovered. Do raise the voltage gradually by using a voltage regulator to some rated value before it is recharged. Generally, the recharging period lasts 1~2 hours. Otherwise, there is the danger of electric shock or exposure.
Never open the front cover while the inverter is power ON.
Otherwise, there is the danger of electric shock.
Never touch the inner side of the inverter while it is power ON,
nor put any foreign matter, i.e., rod or other matter inside the
inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Never open the front cover while the inverter is power ON.
Otherwise, there is the danger of electric shock.
Never touch the inner side of the inverter while it is power ON,
nor put any foreign matter, i.e., rod or other matter inside the
inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Failure
4.3 Failure Parameters Display4.3 Failure Parameters Display
Table 4-3 Failure Codes LCD Display ListTable 4-3 Failure Codes LCD Display List
Chapter 4 Operator panel and its OperationChapter 4 Operator panel and its Operation
DISPLAY CODE
MO
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CATEGORY
Acceleration running over current
Deceleration running over current
Steady-speed running over current
Acceleration running over voltage
Deceleration running over voltage
Steady running over voltage
Over voltage when power off
Under voltage of running
Input side open-phase
Power module failure
Radiator over heat
Inverter overload
Motor overload
external equipment failure
Remain
Current detection error
Keyboard communication failure
COM error
Acceleration running over current
Deceleration running over current
Steady-speed running over current
Acceleration running over voltage
Deceleration running over voltage
Steady running over voltage
Over voltage when power off
Under voltage of running
Input side open-phase
Power module failure
Radiator over heat
Inverter overload
Motor overload
external equipment failure
Remain
Current detection error
Keyboard communication failure
COM error
RemainRemain
HAZARD
CAUTION
Motor insulation should be checked before the inverter is used for the first use or reused after a long-term idle. Be sure the insulation resistance measured is no lower than 5 .
Motor insulation should be checked before the inverter is used for the first use or reused after a long-term idle. Be sure the insulation resistance measured is no lower than 5 .
Try this step only after careful inspection as mentioned in the clauses of 5.1.2. While in trial operation, it is suggested that the motor has vacant load to avoid damage to this mechanical equipment arising from incorrect operation. During this period, if the operating instruction is F010, then the RUN/STOP key control (factory default setting) of the operator panel must be selected. The trial operation steps must be followed as shown in Table 5-1 below.
Try this step only after careful inspection as mentioned in the clauses of 5.1.2. While in trial operation, it is suggested that the motor has vacant load to avoid damage to this mechanical equipment arising from incorrect operation. During this period, if the operating instruction is F010, then the RUN/STOP key control (factory default setting) of the operator panel must be selected. The trial operation steps must be followed as shown in Table 5-1 below.
5.1.3 Trial Operation5.1.3 Trial Operation
Table 5-1 Trial Operation StepsTable 5-1 Trial Operation Steps
Order Operation Description
Switch on, inverter energized.Switch on, inverter energized.
Press .00Hz.
Press .00Hz.
Keep a close eye on the following points:
Is there any abnormal vibration or noise when the motor runs?
Is there any tripping or other abnormality of the inverter?
Does the motor run in the correct way?
Are the values of rotation speed and frequency correct?
Keep a close eye on the following points:
Is there any abnormal vibration or noise when the motor runs?
Is there any tripping or other abnormality of the inverter?
Does the motor run in the correct way?
Are the values of rotation speed and frequency correct?
Press continuously till LED displays 50.00Hz.
Press continuously till LED displays 50.00Hz.
Press continuously till LED displays 0.00Hz.Press continuously till LED displays 0.00Hz.
PressPress
When energized, the inverter is in the state of readiness and LED displays 0.00Hz.When energized, the inverter is in the state of readiness and LED displays 0.00Hz.
Set the frequency to 5.00Hz. This step can be left out if the displayed frequency is already 5.00Hz when energized.
Set the frequency to 5.00Hz. This step can be left out if the displayed frequency is already 5.00Hz when energized.
Motor begins rotating, the frequency displayed on the inverter LED raises from 0.00Hz to 5.00Hz, and the built-in cooling fan begins working.
Motor begins rotating, the frequency displayed on the inverter LED raises from 0.00Hz to 5.00Hz, and the built-in cooling fan begins working.
If there is any anomaly or tripping, stop
running immediately and cut off the
power supply. Please refer to Chapter 7,
find the trouble causes, then proceed trial
operation again after troubleshooting.
If the motor runs in the wrong direction,
change arbitrary two-phase connection of
the output terminal U, V or W.
If there is any anomaly or tripping, stop
running immediately and cut off the
power supply. Please refer to Chapter 7,
find the trouble causes, then proceed trial
operation again after troubleshooting.
If the motor runs in the wrong direction,
change arbitrary two-phase connection of
the output terminal U, V or W.
The motor accelerates rotating and the displayed frequency rises from 5.00Hz to .00Hz. Go to the next step if everything is normal.
The motor accelerates rotating and the displayed frequency rises from 5.00Hz to .00Hz. Go to the next step if everything is normal.
The motor decelerates rotating and the displayed frequency falls from 50.00Hz to 0.00 Hz. Go to the next step if everything is normal.
The motor decelerates rotating and the displayed frequency falls from 50.00Hz to 0.00 Hz. Go to the next step if everything is normal.
The inverter stops outputting, the motor stops running and the trial operation ends. If everything is normal, please repeat the operation for several times.
The inverter stops outputting, the motor stops running and the trial operation ends. If everything is normal, please repeat the operation for several times.
5.2 Cautions for Operation5.2 Cautions for Operation
All the inverter functions are determined by set parameters. ZVF9 series inverter parameters consist of the function codes F000~F166, see the detail in Chapter 6 of this manual. The displayed parameter value of each function code is the factory default value of the inverter before EX factory, which can be modified by the user according to his needs. It is noteworthy that a user shall change the relative function parameters when he amends a parameter because some of the parameters are inter-related. It is not recommended to modify the set parameter value if there is no special requirement, for the factory default setting has been done properly. Otherwise, this may cause damage to the inverter or equipment due to error parameter.In case there is an error alternation of the parameter, please initialize the parameter with reference to the operation method in the clause 4.1.5
Restoring to Factory Default Settings .
All the inverter functions are determined by set parameters. ZVF9 series inverter parameters consist of the function codes F000~F166, see the detail in Chapter 6 of this manual. The displayed parameter value of each function code is the factory default value of the inverter before EX factory, which can be modified by the user according to his needs. It is noteworthy that a user shall change the relative function parameters when he amends a parameter because some of the parameters are inter-related. It is not recommended to modify the set parameter value if there is no special requirement, for the factory default setting has been done properly. Otherwise, this may cause damage to the inverter or equipment due to error parameter.In case there is an error alternation of the parameter, please initialize the parameter with reference to the operation method in the clause 4.1.5
Restoring to Factory Default Settings .
5.2.1 Cautions for Operation5.2.1 Cautions for Operation
Do not open the front cover while the inverter is powered ON.
Otherwise, there is the danger of electric shock.
Do not touch the inner side of the inverter while the power is ON,
nor put any foreign matter, i.e., rod or other matter inside the
inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Do not operate the inverter with wet hands.
If the Retry Mode is set, please put a warning sign like KEEP
CLEAR or HAZARD in an eye-catching place before the
equipment to avoid sudden restart of the equipment after a trip stop
that may result in injury to personnel.
Do not open the front cover while the inverter is powered ON.
Otherwise, there is the danger of electric shock.
Do not touch the inner side of the inverter while the power is ON,
nor put any foreign matter, i.e., rod or other matter inside the
inverter. Otherwise, it may result in serious damage to the
equipment or death to personnel.
Do not operate the inverter with wet hands.
If the Retry Mode is set, please put a warning sign like KEEP
CLEAR or HAZARD in an eye-catching place before the
equipment to avoid sudden restart of the equipment after a trip stop
that may result in injury to personnel.
If the inverter runs at a frequency higher than 50Hz, DO confirm it is within the speed range acceptable by your motor bearing and mechanical device. Otherwise, there is the danger of damage to the motor.
Derating should be done before use due to less effective of heat dissipation when a general motor runs at a low frequency. If it is a constant torque load, then a forced method or a special variable frequency motor should be used to release heat.
DO cut off the power supply of an inverter set aside for a long time to avoid foreign matter or other things enter in it which may cause damage to the inverter or even lead to fire.
If the inverter runs at a frequency higher than 50Hz, DO confirm it is within the speed range acceptable by your motor bearing and mechanical device. Otherwise, there is the danger of damage to the motor.
Derating should be done before use due to less effective of heat dissipation when a general motor runs at a low frequency. If it is a constant torque load, then a forced method or a special variable frequency motor should be used to release heat.
DO cut off the power supply of an inverter set aside for a long time to avoid foreign matter or other things enter in it which may cause damage to the inverter or even lead to fire.
Chapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of Inverter
HAZARD
WARNING
5.3 Examples of Use5.3 Examples of Use
This manual provides following examples for users' reference on the use of
inverter.
This manual provides following examples for users' reference on the use of
inverter.
5.3.1 Eg. 1: Run or stop the inverter with operator panel, and feed the frequency with operator panel potentiometer.5.3.1 Eg. 1: Run or stop the inverter with operator panel, and feed the frequency with operator panel potentiometer.
Figure 5-2 Eg.1 Wiring Diagram Figure 5-2 Eg.1 Wiring Diagram
F009 This indicates the selection of frequency setting. If setting this value to
0 , the frequency will be fed by the potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
0 , the inverter will be controlled by the operator panel.
Run or stop the inverter with keys on the operator panel.
Rotate the operator panel potentiometer to adjust the speed.
F009 This indicates the selection of frequency setting. If setting this value to
0 , the frequency will be fed by the potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
0 , the inverter will be controlled by the operator panel.
Run or stop the inverter with keys on the operator panel.
Rotate the operator panel potentiometer to adjust the speed.
Three-phase AC Power SupplyThree-phase AC Power Supply
Relay Failure Output
Relay Failure Output
Voltage OutputVoltage Output
~~
If the inverter is used beyond the range of allowable working voltage, then an extra step-up or step-down voltage transformer shall be configured.
Due to thin air in a place where the altitude is higher than 1,000m, the heat dissipation of inverter will be less effective. Hence derating should be done before use. In general, when the height rises by 1,000m, the rated voltage of the inverter shall reduce by 10%. Refer to Figure 5-1 for details of the derating curve.
If the inverter is used beyond the range of allowable working voltage, then an extra step-up or step-down voltage transformer shall be configured.
Due to thin air in a place where the altitude is higher than 1,000m, the heat dissipation of inverter will be less effective. Hence derating should be done before use. In general, when the height rises by 1,000m, the rated voltage of the inverter shall reduce by 10%. Refer to Figure 5-1 for details of the derating curve.
IoutIout
90%90%
80%80% 10001000 20002000 30003000 40004000MM
Figure 5-1 Diagram of Inverter Derating CurveFigure 5-1 Diagram of Inverter Derating Curve
DO NOT touch the radiator or charging resistor of the inverter
with hand(s). Otherwise, there is the possibility of getting scalded.
DO NOT proceed direct start-stop operation frequently with a
contactor or any other switch devices in the inverter input side. As
large charging current exists in the main circuit of the inverter,
frequent power-on/off may produce cumulative effect resulting in
heat fatigue of inverter components and great reduction of service
life of the inverter.
DO NOT touch the radiator or charging resistor of the inverter
with hand(s). Otherwise, there is the possibility of getting scalded.
DO NOT proceed direct start-stop operation frequently with a
contactor or any other switch devices in the inverter input side. As
large charging current exists in the main circuit of the inverter,
frequent power-on/off may produce cumulative effect resulting in
heat fatigue of inverter components and great reduction of service
life of the inverter.
In case abnormalities occur, such as smoke, off odor, strange sound, DO cut off the power supply immediately, overhaul the equipment or turn to the agent for help via phone call.
In case abnormalities occur, such as smoke, off odor, strange sound, DO cut off the power supply immediately, overhaul the equipment or turn to the agent for help via phone call.
100%100%
Chapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of Inverter
CAUTION
FORBIDDEN
COMPULSORY
Eg.2: Run or stop the inverter with external terminals, and feed the frequency with external potentiometer.Eg.2: Run or stop the inverter with external terminals, and feed the frequency with external potentiometer.
Figure 5-3 Wiring Diagram of Eg. 2Figure 5-3 Wiring Diagram of Eg. 2
F009 This indicates the selection of frequency setting. If setting this value to
3 , the frequency will be set by external voltage signal V or external potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111 This indicates the selection of the function of input terminal X1. If setting
this value to 15 , then the external reset input is performed.
FWD-COM off, motor forwards. REV-COM on, motor reverses. FWD, REV-COM
on or off at the same time, inverter stops running. X1-COM on, failure resets.
Realize speed control by regulating the value of V (controlled by 1.5~5K/3W
potentiometer).
F009 This indicates the selection of frequency setting. If setting this value to
3 , the frequency will be set by external voltage signal V or external potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111 This indicates the selection of the function of input terminal X1. If setting
this value to 15 , then the external reset input is performed.
FWD-COM off, motor forwards. REV-COM on, motor reverses. FWD, REV-COM
on or off at the same time, inverter stops running. X1-COM on, failure resets.
Realize speed control by regulating the value of V (controlled by 1.5~5K/3W
potentiometer).
~~
Forward
Reverse
Reset
Forward
Reverse
Reset
~~
Multistage Speed Control Terminal
Multistage Speed Control Terminal
Free StopFree Stop
Eg.3: Run or stop the inverter with external terminals by adopting operation manner at multistage speed.Eg.3: Run or stop the inverter with external terminals by adopting operation manner at multistage speed.
Figure 5-4 Eg.3 Wiring DiagramFigure 5-4 Eg.3 Wiring Diagram
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111~F113 This indicates the selection of multi-function terminal X1~X3, set to 1,
2 and 3 multistage speed control terminal in order.
F114 (X4 multi-function selection). Select 8---External free stop.
F081~F087 Multi-speed frequency setting, which can be set in 7 stages. Factory
defaults are preferred.
FWD COM off, motor forwards; REV-COM off, motor reverses.
FWD REV COM on or off simultaneously, inverter stops.
Connecting an arbitrary terminal of X1~X3 to COM (7 pairs of such complex in total),
the inverter will run at the frequency of multistage speed selected by X1~X3.
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111~F113 This indicates the selection of multi-function terminal X1~X3, set to 1,
2 and 3 multistage speed control terminal in order.
F114 (X4 multi-function selection). Select 8---External free stop.
F081~F087 Multi-speed frequency setting, which can be set in 7 stages. Factory
defaults are preferred.
FWD COM off, motor forwards; REV-COM off, motor reverses.
FWD REV COM on or off simultaneously, inverter stops.
Connecting an arbitrary terminal of X1~X3 to COM (7 pairs of such complex in total),
the inverter will run at the frequency of multistage speed selected by X1~X3.
Chapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of Inverter
Three-phase AC Power SupplyThree-phase AC Power Supply
Relay Failure Output
Relay Failure Output
Voltage OutputVoltage Output
Relay Failure Output
Relay Failure Output
Voltage OutputVoltage Output
Forward
Reverse
Forward
Reverse
Three-phase AC Power SupplyThree-phase AC Power Supply
5.3.4 Eg.4 Run or stop the inverter with external terminals, feed the frequency with
external potentiometer and multiple motors run in parallel.
5.3.4 Eg.4 Run or stop the inverter with external terminals, feed the frequency with
external potentiometer and multiple motors run in parallel.
~~
F009 This indicates the selection of frequency setting. If setting this value to
3 , the frequency will be set by external voltage signal V or external
potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111 This indicates the selection of the function of input terminal X1. If setting
this value to 15 , then the external reset input is performed.
FWD-COM off, motor forwards. REV-COM off, motor reverses. FWD, REV-COM
on or off simultaneously, inverter stops running. X1-COM off, failure resets.
Realize speed control by regulating the value of V (controlled by 1.5~5K/3W
potentiometer).
Each set of motor uses thermal relay to have an overload protection.
The value of electronic thermal relay is determined by the parameter F148 through
tests.
F009 This indicates the selection of frequency setting. If setting this value to
3 , the frequency will be set by external voltage signal V or external
potentiometer.
F010 This indicates the selection of operating instruction. If setting this value to
1 , the inverter will be controlled by external terminals.
F111 This indicates the selection of the function of input terminal X1. If setting
this value to 15 , then the external reset input is performed.
FWD-COM off, motor forwards. REV-COM off, motor reverses. FWD, REV-COM
on or off simultaneously, inverter stops running. X1-COM off, failure resets.
Realize speed control by regulating the value of V (controlled by 1.5~5K/3W
potentiometer).
Each set of motor uses thermal relay to have an overload protection.
The value of electronic thermal relay is determined by the parameter F148 through
tests.
Figure 5-5 Eg.4 Wiring DiagramFigure 5-5 Eg.4 Wiring Diagram
~~
~~
Electronic Thermal RelayElectronic Thermal Relay
~~
Eg.5: Multiple Inverter Ratio Interlocking Operation ControlEg.5: Multiple Inverter Ratio Interlocking Operation Control
Primary machinePrimary machine
b u sb u s
Figure 5-6 Eg.5 Wiring DiagramFigure 5-6 Eg.5 Wiring Diagram
F155 Local communication address: Set this address to 0 and make the inverter as a host.
F156 Communication data format: Set all the data formats of the inverter to the same
value.
F157 Communication baud rate: Set all the baud rates of the inverter to the same value.
Secondary Machine Setting
F009 Selection of frequency setting: Set this value to 6, the frequency will be set by COM
(serial communication).
F010 Selection of operating instruction: Set this value to 2 , the inverter will be
controlled by COM.
F155 Local communication address: Set this address to 1~30, which means 30 sets of
inverters can be connected at this address maximally).
F156 Communication data format: Be the same as the primary machine.
F157 Communication baud rate: Be the same as the primary machine.
F158 Interlocking setting ratio: 0.01~10, set as per user s demand.
Only such operations can be done on the master inverter, such as start, stop and so the like.
Other operations should be matched with the master inverter.
F155 Local communication address: Set this address to 0 and make the inverter as a host.
F156 Communication data format: Set all the data formats of the inverter to the same
value.
F157 Communication baud rate: Set all the baud rates of the inverter to the same value.
Secondary Machine Setting
F009
F010 Selection of operating instruction: Set this value to 2 , the inverter will be
controlled by COM.
F155 Local communication address: Set this address to 1~30, which means 30 sets of
inverters can be connected at this address maximally).
F156 Communication data format: Be the same as the primary machine.
F157 Communication baud rate: Be the same as the primary machine.
F158 Interlocking setting ratio: 0.01~10, set as per user s demand.
Only such operations can be done on the master inverter, such as start, stop and so the like.
Other operations should be matched with the master inverter.
Selection of frequency setting: Set this value to 6, the frequency will be set by COM
(serial communication).
Primary Machine SettingPrimary Machine Setting
Chapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of Inverter
ForwardReverseReset
ForwardReverseReset
Three-phase AC Power Supply
Three-phase AC Power Supply
Relay Failure Output
Relay Failure Output
Voltage OutputVoltage Output
ForwardReverseReset
ForwardReverseReset
Three-phase AC Power Supply
Three-phase AC Power Supply
Relay Failure Output
Relay Failure Output
Voltage OutputVoltage Output
Secondary machine 1Secondary machine 1
Secondary machine nSecondary machine n
5.3.6 Eg.6: PID Constant Pressure Water Supply Control5.3.6 Eg.6: PID Constant Pressure Water Supply Control
Figure 5-7 Eg.6 Wiring DiagramFigure 5-7 Eg.6 Wiring Diagram
F130 PID motion selection: Set the value to 1, then PID selection is valid.F131 PID given path selection: Set the value to 0, then the selection of / is
valid.F132 Given digital setting: Set according to actual demand. Set it to 5.0V herein.F133 PID Feedback path selection: Set the value to 1, then external current is
selected.F134 PID Feedback flow gain: Set according to actual demand. No regulation
here.F135 PID feedback polarity selection: Set the value to 0, then positive is selected.F136 Proportional gain P: Set according to actual demand. No regulation here.F137 Integral time constant TI: Set according to actual demand. No regulation
here.F138 Derivative time constant DI: Set according to actual demand. No regulation
here.F139 Sampling period: No need to alter.F140 Deviation limit: Set according to actual demand. No regulation here.
F130 PID motion selection: Set the value to 1, then PID selection is valid.F131 PID given path selection: Set the value to 0, then the selection of / is
valid.F132 Given digital setting: Set according to actual demand. Set it to 5.0V herein.F133 PID Feedback path selection: Set the value to 1, then external current is
selected.F134 PID Feedback flow gain: Set according to actual demand. No regulation
here.F135 PID feedback polarity selection: Set the value to 0, then positive is selected.F136 Proportional gain P: Set according to actual demand. No regulation here.F137 Integral time constant TI: Set according to actual demand. No regulation
here.F138 Derivative time constant DI: Set according to actual demand. No regulation
here.F139 Sampling period: No need to alter.F140 Deviation limit: Set according to actual demand. No regulation here.
Voltage outputVoltage output
~~
Power frequency running
Power frequency running
Variable frequency runningVariable frequency running
F141 Sleep threshold: Set according to actual demand. No regulation here.
F142 Revoke threshold: Set according to actual demand. No regulation here.
F143 Check-out time of sleep/revoke threshold: Set according to actual demand.
No regulation here.
Other parameters remain the factory defaults. Corresponding initiate modes and
other operations shall be modified in the light of actual conditions and requirements.
F141 Sleep threshold: Set according to actual demand. No regulation here.
F142 Revoke threshold: Set according to actual demand. No regulation here.
F143 Check-out time of sleep/revoke threshold: Set according to actual demand.
No regulation here.
Other parameters remain the factory defaults. Corresponding initiate modes and
other operations shall be modified in the light of actual conditions and requirements.
WARNINGWARNING
The contactor KM1 and KM2 must be designed in interlocked
manner to realize converting between power frequency and
variable frequency. It is forbidden to close simultaneously.
Otherwise, it may lead to permanent damage to the inverter.
The contactor KM1 and KM2 must be designed in interlocked
manner to realize converting between power frequency and
variable frequency. It is forbidden to close simultaneously.
Otherwise, it may lead to permanent damage to the inverter.
Chapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of InverterChapter 5 Operation of Inverter
Three-phase AC Power Supply
Three-phase AC Power Supply
ForwardReverseReset
ForwardReverseReset Relay
Failure Output
Relay Failure Output
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
6.1 Schedule of Function Parameters6.1 Schedule of Function Parameters
The mark indicates the setting value of parameter can be
modified no matter when the inverter is shutdown or running.
The mark indicates the setting value of parameter can be
modified only when the inverter is shutdown, and can not be
modified when the inverter is running.
The mark indicates the parameter can be displayed only
and can not be modified.
The mark indicates the setting value of parameter can be
modified no matter when the inverter is shutdown or running.
The mark indicates the setting value of parameter can be
modified only when the inverter is shutdown, and can not be
modified when the inverter is running.
The mark indicates the parameter can be displayed only
and can not be modified.
TipsTips
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnit Minimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Software Version numberSoftware Version numberInverter Specification DisplayInverter Specification Display
Parameter Initiating / Removing Failure Record
Parameter Initiating / Removing Failure Record
RemainRemain
Selection of operation control mode
Selection of operation control mode
Selection of motor rotating directionSelection of motor rotating direction
0:Unidirectional with the set direction
1:Opposite to the set direction.
2:No reversal.
0:Unidirectional with the set direction
1:Opposite to the set direction.
2:No reversal.
Selection of frequency setting manner
Selection of frequency setting manner
0:Set by the potentiometer of operator
panel.
1: Set by external terminal
2:Set by analog voltage signal V
(0~10VDC)
3:or the external potentiometer.
4:Set by analog current signal I
(0~20mA).
5:Set by analog input assembly.
6:Set by 485 COM.
0:Set by the potentiometer of operator
panel.
1: Set by external terminal
2:Set by analog voltage signal V
(0~10VDC)
3:or the external potentiometer.
4:Set by analog current signal I
(0~20mA).
5:Set by analog input assembly.
6:Set by 485 COM.
Setting of operation frequencySetting of operation frequency
Operation frequency is set within 0.00Hz~upper limit of the frequency.Operation frequency is set within 0.00Hz~upper limit of the frequency.
0:Controlled by RUN/STOP key on
operator panel.
1: Controlled by external terminal
2:Controlled by 485 COM.
0:Controlled by RUN/STOP key on
operator panel.
1: Controlled by external terminal
2:Controlled by 485 COM.
Maximum output frequencyMaximum output frequency
Selection of V/F curve modeSelection of V/F curve mode
Selection of acceleration /deceleration mannerSelection of acceleration /deceleration manner
Accelerating period 1Accelerating period 1Decelerating period 1Decelerating period 1
Upper limit of frequencyUpper limit of frequency
0:Linearity (Constant torque mode)
1:Square (Quadratic torque mode)
0:Linearity (Constant torque mode)
1:Square (Quadratic torque mode)
Linear S curveLinear S curve
Lower limit ~ maximum output frequencyLower limit ~ maximum output frequency
Determined in accordance with specifications
Determined in accordance with specifications
6.1.1 Basic Functions6.1.1 Basic Functions
0:Parameter is in the status of modification.1:Remove failure record information.2:All the parameters return to factory default settings.
0:Parameter is in the status of modification.1:Remove failure record information.2:All the parameters return to factory default settings.
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Chapter 6 Description of Function Parameters
Determined in accordance with specifications
Determined in accordance with specifications
6.1.4 Auxiliary Functions6.1.4 Auxiliary Functions
0:Current output frequency of the
inverter
1:Current set frequency of the inverter
2:Output current
3:Output voltage
4:Motor rotating speed
5:Linear speed of running
6:Linear speed setting
7:DC bus bar voltage
8:Power module temperature
9:PID target value
10:PID feedback value
11:Counter value
12:Cumulative time of current
running (Hours)
13:Input terminal status
0:Current output frequency of the
inverter
1:Current set frequency of the inverter
2:Output current
3:Output voltage
4:Motor rotating speed
5:Linear speed of running
6:Linear speed setting
7:DC bus bar voltage
8:Power module temperature
9:PID target value
10:PID feedback value
11:Counter value
12:Cumulative time of current
running (Hours)
13:Input terminal status
Selection of Power On display items
Selection of Power On display items
RemainRemain
Display coefficient of linear speed
Display coefficient of linear speed
Display coefficient of closed-loop control
Display coefficient of closed-loop control
Selection of REV/JOG key functionSelection of REV/JOG key function
Two-wire/Three-wire running control
Two-wire/Three-wire running control
Accelerating period 2Accelerating period 2
Decelerating period 2Decelerating period 2
Lower limit of frequencyLower limit of frequency
RemainRemain
Upper limit of frequencyUpper limit of frequency
Basic Functions (Continued) Basic Functions (Continued)
Jog FunctionsJog Functions
Jog running frequency
Jog accelerating period
Jog decelerating period
Jog running frequency
Jog accelerating period
Jog decelerating period
6.1.3 Start & Stop Function6.1.3 Start & Stop Function
0:Start at the starting frequency1:Brake first and start then2: Start in the mode of rotation speed tracking
0:Start at the starting frequency1:Brake first and start then2: Start in the mode of rotation speed tracking
Halt modeHalt mode0:Decelerating stop
1: Free stop
0:Decelerating stop
1: Free stop
Selection of starting modeSelection of starting mode
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Determined in accordance with specifications
Determined in accordance with specificationsDetermined in accordance with specifications
Determined in accordance with specifications
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnit Minimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnit Minimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnitMinimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnit Minimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Starting frequency
Starting frequency holding time
Starting DC braking voltage
Starting DC braking time
FWD/REV dead time
Shutdown DC braking starting frequency
Shutdown DC braking voltage
Shutdown DC braking time
Remain
0:Two-wire control mode 11:Two-wire control mode 22:Three-wire control mode
RemainRemain
Special FunctionsSpecial Functions 6.1.6 Analog Input/Output Functions6.1.6 Analog Input/Output Functions
Positive bias
Negative bias
Positive bias
Negative bias
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Determined in accordance with specifications
Determined in accordance with specifications
Determined in accordance with specifications
Determined in accordance with specifications
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
0:Forbidden 1:Allowable
0:Forbidden 1:Allowable
0:Forbidden 1:Allowable
Selection of automatic energy-saving operation
Setting of slip compensation
Selection of AVR function
Torque lifting
Carrier frequency
Leap frequency 1Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Range of leap frequency 1
Leap frequency 2
Range of leap frequency 2
Reference frequency of acceleration/deceleration period
Selection of retry mode
Wait time for restart mode
Frequency arrival checkout range (FAR)
Setting of FDT level0.00Hz~upper limit of frequency
PDT lagged value
Overload pre-alarm level
Overload pre-alarm action period
Remain
Remain
Lower limit of analog voltage inputUpper limit of analog voltage input
Lower limit of analog current IUpper limit of analog current I
Bipolarity zero offset of analog input
Biasing direction of the frequency corresponding to the lower limit of analog input
Positive bias
Negative bias
Positive bias
Negative bias
Biasing direction of the frequency corresponding to the Upper limit of analog input
Corresponding set frequency of Min. analog input
0.00Hz~upper limit of frequency
0.00Hz~Lower limit of frequency
Corresponding set frequency of Max. analog input
Delay period of analog input signal
Analog meter output AM
0:Running frequency
1:Motor rotation speed
2:Output current
3:Output voltage
4:PID feedback value
Proportional gain of analog meter output AM
Analog meter output AM bias
Analog input assembly settingAnalog input assembly setting
External voltage V External current I
External voltage V External current I
External current I External voltage V
External current I External voltage V
External voltage V External current I
External voltage V External current I
External current I External voltage V
External current I External voltage V
Analog Functions (Continued)Analog Functions (Continued)
Multi-speed / Program Running FunctionsMulti-speed / Program Running Functions
Multistage Speed/Programmable Running Functions (Continued)Multistage Speed/Programmable Running Functions (Continued)
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Function CodeFunction Code
NameName Range of settingRange of setting UnitUnit Minimum UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Remain
Remain
Selection of programmable multistage speed running
0:Non operation
1:Single cycling
2:Continuous cycling
3:Maintaining ultimate
value after singe cycling
4:Wobbulation running
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Lower limit of frequency ~ upper limit of frequency
Output frequency at the first stage speedOutput frequency at the second stage speedOutput frequency at the third stage speed
Output frequency at the fifth stage speed
Output frequency at the fourth stage speed
Output frequency at the sixth stage speedOutput frequency at the seventh stage speed
First stage speed running time
Selection of running direction at the first stage speed
Selection of running direction at the second stage speed
Selection of running direction at the third stage speed
Selection of running direction at the fourth stage speed
Selection of running direction at the first stage speed
Selection of running direction at the sixth stage speed
Selection of running direction at the seventh stage speed
Second stage speed add-subtract time
Second stage speed running time
Third stage speed running time
fourth stage speed running time
Fifth stage speed running time
Sixth stage speed running time
Seventh stage speed running time
Remain
Remain
First stage speed add-subtract time
Third stage speed add-subtract time
Fourth stage speed add-subtract time
Fifth stage speed add-subtract time
Sixth stage speed add-subtract time
Seventh stage speed add-subtract time
Functions of Input/Output TerminalsFunctions of Input/Output Terminals
0:No function
1:Multistage speed
selection 1
2:Multistage speed
selection 2
3:Multistage speed
selection 3
4:Accelerating/decelerating
period terminals
5:Remain
6:FRD JOG control
7:REV JOG control
8:Free stop control
9:Frequency raising
instruction (UP)
10:Frequency decreasing
instruction (DOWN)
11:External equipment
failure input
12:Easy PLC pause
13:Three-wire running
control
14:DC braking instruction
15:External reset input
16:Input of decelerating
shutdown control
17:Counter zero-clearance
input
18:Counter impulse signal
input (The input of counter
impulse signal terminal X6
is valid.)
0:No function
1:Multistage speed
selection 1
2:Multistage speed
selection 2
3:Multistage speed
selection 3
4:Accelerating/decelerating
period terminals
5:Remain
6:FRD JOG control
7:REV JOG control
8:Free stop control
9:Frequency raising
instruction (UP)
10:Frequency decreasing
instruction (DOWN)
11:External equipment
failure input
12:Easy PLC pause
13:Three-wire running
control
14:DC braking instruction
15:External reset input
16:Input of decelerating
shutdown control
17:Counter zero-clearance
input
18:Counter impulse signal
input (The input of counter
impulse signal terminal X6
is valid.)
Function selection of multi-function input terminal X1
Function selection of multi-function input terminal X1
Function selection of multi-function input terminal X2
Function selection of multi-function input terminal X2
Function selection of multi-function input terminal X3
Function selection of multi-function input terminal X3
Function selection of multi-function input terminal X4
Function selection of multi-function input terminal X4
Function selection of multi-function input terminal X5
Function selection of multi-function input terminal X5
Function selection of multi-function input terminal X6
Function selection of multi-function input terminal X6
Functions of Input/Output Terminals (Continued)Functions of Input/Output Terminals (Continued)
0:Indication for in
operation
1:Frequency/Speed arrival
signal (FAR)
2:Frequency/Speed level
detecting signal (FDT)
3:Inverter Under-voltage
lockout
4:External Failure Input
5:Upper limit of output
frequency arrival
6:Lower limit of output
frequency arrival
7:Inverter zero rotary in
operation instruction
8:Programmable multistage
speed running ends
9:Inverter overload alarm signal
10:Count to output
0:Indication for in
operation
1:Frequency/Speed arrival
signal (FAR)
2:Frequency/Speed level
detecting signal (FDT)
3:Inverter Under-voltage
lockout
4:External Failure Input
5:Upper limit of output
frequency arrival
6:Lower limit of output
frequency arrival
7:Inverter zero rotary in
operation instruction
8:Programmable multistage
speed running ends
9:Inverter overload alarm signal
10:Count to output
Function selection of collector output terminal Y1
Function selection of collector output terminal Y1
Function selection of collector output terminal Y2
Function selection of collector output terminal Y2
RemainRemain
Counter FunctionsCounter Functions
Invalid
Up count mode
Down count mode
Invalid
Up count mode
Down count mode
Stop counting
Recounting
Stop counting
Recounting
Selection of counting modesSelection of counting modes
Counting valueCounting value
Counting coefficientCounting coefficient
Count to option processingCount to option processing
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
RemainRemain
RemainRemain
Motor ParametersMotor Parameters
Motor rated frequency
Motor rated voltage
Motor rated current
Motor rated rotating speed
Motor rated frequency
Motor rated voltage
Motor rated current
Motor rated rotating speed
PID action selectionPID action selection
Selection of PID target value setting mode
Selection of PID target value setting mode
PID target value settingPID target value setting
Selection of
feedback conditions
Selection of
feedback conditions
PID feedback flow gainPID feedback flow gain
PID feedback polarity selectionPID feedback polarity selection
Proportional gain (P)Proportional gain (P)
Integral time constant TIIntegral time constant TI
Differential time constant DIDifferential time constant DI
PID FunctionsPID Functions
0:
1:
Invalid
Valid
0:Invalid
1:Valid
0:
1:
2:
3:
Set by operator
panel / key
Set by external voltage
signal V(0~10VDC)
Set by external current
signal I (0~20mA)
Set by 485 COM
0:Set by operator
panel / key
1:Set by external voltage
signal V(0~10VDC)
2:Set by external current
signal I (0~20mA)
3:Set by 485 COM
0:
1:
Set by external voltage signal V 0~10VDC
Set by external current signal I 0~20mA
0:Set by external voltage signal V 0~10VDC1:Set by external current signal I 0~20mA
PID Functions (Continued)PID Functions (Continued)
6.1.12 protecion functions6.1.12 protecion functions
Sampling period
Deviation limit
Sleep threshold
Revoke threshold
Remain
Sampling period
Deviation limit
Sleep threshold
Revoke threshold
Remain
Overload & overheat protection methodOverload & overheat protection method
Forbidden 1:Allowable
Forbidden 1:Allowable
Forbidden 1:Allowable
Forbidden 1:Allowable
Forbidden 1:Allowable
Forbidden 1:Allowable
0:
1:
Inverter Stop Output
Current-limiting
running
0:Inverter Stop Output
1:Current-limiting
running
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Determined in accordance with specifications
Determined in accordance with specificationsDetermined in accordance with specifications
Determined in accordance with specifications
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Check-out time for sleep/revoke threshold
Check-out time for sleep/revoke threshold
Inverter input open-phase protection Inverter input open-phase protection
Over-voltage stall proof functionOver-voltage stall proof functionMotor thermal relay protection coefficientMotor thermal relay protection coefficient
Select ion of automatic current-limiting functionSelect ion of automatic current-limiting functionAcceleration over-current stall proof levelAcceleration over-current stall proof levelConstant speed over-current stall proof levelConstant speed over-current stall proof level
Failure self-resetting timesFailure self-resetting times
Failure self-resetting intervalFailure self-resetting interval
RemainRemain
485 Communication Functions485 Communication Functions
No parity
1:Even parity
2:Odd parity (1-bit starting
location, 8-bit data location,
1-bit stop location)
No parity
1:Even parity
2:Odd parity (1-bit starting
location, 8-bit data location,
1-bit stop location)
Local address of COMLocal address of COM
Data format of COMData format of COM
COM baud rateCOM baud rate
Selection of COM linking ratioSelection of COM linking ratio
Main station settingMain station setting
Other FunctionsOther Functions
0:All the parameters are allowable to be modified, but some parameters can not be modified when the inverter is in operation.1:Other parameters are prohibited to be modified except the Fig. setting frequency and this parameter.2:All the parameters are prohibited to be modified except this parameter.
0:All the parameters are allowable to be modified, but some parameters can not be modified when the inverter is in operation.1:Other parameters are prohibited to be modified except the Fig. setting frequency and this parameter.2:All the parameters are prohibited to be modified except this parameter.
Selection of parameter protectionSelection of parameter protection
Other Functions (Continued)Other Functions (Continued)
No memory memoryNo memory memory
Fan continuous running
Fan-controlled running
Fan continuous running
Fan-controlled running
Invalid ValidInvalid Valid
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Function CodeFunction Code NameName Range of settingRange of setting UnitUnit Minimum
UnitMinimum Unit
Factory Default Setting
Factory Default Setting
Operation ModificationOperation Modification
Remain
Actual running time (S)
Actual running time (H)
Frequency power failure memory
Ventilator fan control
PWM adaptive control
When the frequency setting mode selects / F009=1 on the operator panel, this parameter will be the initial setting frequency. In the condition of monitoring mode, the frequency can be modified directly by / key on the operator panel.
When the frequency setting mode selects / F009=1 on the operator panel, this parameter will be the initial setting frequency. In the condition of monitoring mode, the frequency can be modified directly by / key on the operator panel.
The running frequency upper value is limited by the upper limit of
frequency (F017) and the lower value is limited by the lower limit of
frequency (F018).
When the inverter runs at programmable multistage speed, F008 is also
the set frequencyat the first stage speed.
The running frequency upper value is limited by the upper limit of
frequency (F017) and the lower value is limited by the lower limit of
frequency (F018).
When the inverter runs at programmable multistage speed, F008 is also
the set frequency at the first stage speed.
F009 Setting Range:0 6 Factory Default Value: 1Selection of frequency setting modeF009 Selection of frequency setting mode Setting Range:0 6 Factory Default Value: 1
This function is used to select the setting mode of inverter running frequency.0 Set by the operator panel potentiometer.1 Set by operator panel / key. 2 Set by external terminal UP/DW.3 Set by the external analog voltage signal V (0~10VDC) or the external potentiometer.4 Set by analog current signal I (0~20mA).5 Set by analog input assembly.6 Set by 485 COM.(serial communication).
This function is used to select the setting mode of inverter running frequency.0 Set by the operator panel potentiometer.1 Set by operator panel / key. 2 Set by external terminal UP/DW.3 Set by the external analog voltage signal V (0~10VDC) or the external potentiometer.4 Set by analog current signal I (0~20mA).5 Set by analog input assembly.6 Set by 485 COM.(serial communication).
See F077 for analog input assembly setting.
When the frequency setting mode selects 2 (F009=2), which
means to set the frequency by external terminal UP/DW, one of the
multi-function input terminals X1 X6 must select 9 which
means the frequency goes up and another must select 10 which
means the frequency goes down (see F111~F116 for detail).
Otherwise, this function will be invalid. Then the short circuit
between the selected terminals and COM terminals can lead to
frequency UP/DW separately.
See F077 for analog input assembly setting.
When the frequency setting mode selects 2 (F009=2), which
means to set the frequency by external terminal UP/DW, one of the
multi-function input terminals X1 X6 must select 9 which
means the frequency goes up and another must select 10 which
means the frequency goes down (see F111~F116 for detail).
Otherwise, this function will be invalid. Then the short circuit
between the selected terminals and COM terminals can lead to
frequency UP/DW separately.
6.2 Detailed Instructions on Function Parameters6.2 Detailed Instructions on Function Parameters
F000 : *.*Software Edition No. Setting Range:None Factory Default ValueF000 Software Edition No. Setting Range:None Factory Default Value: *.*
This parameter is used to view the inverter software edition. It can be displayed only and cannot be modified.This parameter is used to view the inverter software edition. It can be displayed only and cannot be modified.
F001 : *.*Setting Range:None Factory Default ValueF001 Setting Range:None Factory Default Value: *.*
This parameter is used to view the specification of the inverter. The rated voltage, current and maximum carrier frequency of the inverter is related to this parameter. Please check and make sure it is the right one that you've ordered with reference to the table below.
This parameter is used to view the specification of the inverter. The rated voltage, current and maximum carrier frequency of the inverter is related to this parameter. Please check and make sure it is the right one that you've ordered with reference to the table below.
seriesseries
Setting Range Factory Default ValueSetting Range Factory Default Value
0: Indicates the parameter is in the modification status.This indicates the inverter is in the
normal status of data reading and writing.
1: Removal of failure records.
When setting the parameter to 1 , all the failure records will be deleted.
2: Data initiating
When setting the parameter to 2 , all the parameters will restore factory defaults.
0: Indicates the parameter is in the modification status.This indicates the inverter is in the
normal status of data reading and writing.
1: Removal of failure records.
When setting the parameter to 1 , all the failure records will be deleted.
2: Data initiating
When setting the parameter to 2 , all the parameters will restore factory defaults.
RemainRemain
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Display of the inverter
specifications
Display of the inverter
specifications
Rated current (A)
Maximum carrier frequency
seriesseries
Rated current (A)
Maximum carrier frequency
seriesseries
Rated current (A)
Maximum carrier frequency
Parameter initiating/Clear failure recordParameter initiating/Clear failure record
Running frequency settingRunning frequency setting
Setting Range:0.00Hz
Upper limit of frequency
Setting Range:0.00Hz
Upper limit of frequencyFactory Default Value:50.00HzFactory Default Value:50.00Hz
F010 Setting Range:0 2 Factory Default Value: 0F010 Setting Range:0 2 Factory Default Value: 0
VVmaxmax
Output FrequencyOutput Frequency ff11 ff22 ff44
ff33
0
1
2
This function is used to set the control modes when the operation commands such as FWD, REV,
JOG and STOP are given to the inverter.
Controlled by RUN or STOP key on the operator panel.
Run or stop the motor by pressing RUN, STOP or REV/JOG key on the operator panel.
Controlled by external terminal(s)
Run or stop the motor by connecting or disconnecting the external terminal FWD/REVCOM.
Controlled by 485 COM.
Run or stop the motor through 485 COM port.
This function is used to set the control modes when the operation commands such as FWD, REV,
JOG and STOP are given to the inverter.
0 Controlled by RUN or STOP key on the operator panel.
Run or stop the motor by pressing RUN, STOP or REV/JOG key on the operator panel.
1 Controlled by external terminal(s)
Run or stop the motor by connecting or disconnecting the external terminal FWD/REVCOM.
2 Controlled by 485 COM.
Run or stop the motor through 485 COM port.
F011 Setting Range:0 2 Factory Default Value: 0F011 Setting Range:0 2 Factory Default Value: 0
Unidirectional with the set directionOpposite to the set direction.No reversal.
Unidirectional with the set directionOpposite to the set direction.No reversal.
This function is used to set the allowable maximum frequency of the inverter, as shown in f4 of Fig. 6-1.The f2 in this Fig. is generally defined as the basic frequency, the output frequency corresponding to the rated voltage output.The Vmax in this Fig. is the maximum output voltage of the inverter.
This function is used to set the allowable maximum frequency of the inverter, as shown in f4 of Fig. 6-1.The f2 in this Fig. is generally defined as the basic frequency, the output frequency corresponding to the rated voltage output.The Vmax in this Fig. is the maximum output voltage of the inverter.
Fig. 6-1 Diagram of Voltage FrequencyFig. 6-1 Diagram of Voltage Frequency
F012 Setting Range:50.00 400.0Hz Factory Default Value: 50.00 HzF012 Setting Range:50.00 400.0Hz Factory Default Value: 50.00 Hz
00
11
F013 Setting Range:0 1 Factory Default Value: 0F013 Setting Range:0 1 Factory Default Value: 0
0
1
Linearity (Constant torque mode)
The output voltage of the inverter is in direct proportion to frequency, which is applicable to
most loads as shown in the line of Fig. 6-2.
Square (Quadratic torque mode)
The output voltage of the inverter is in conic to frequency, which is applicable to fans, water
pumps and loads so the like, as shown in the curve of Fig. 6-2.
0 Linearity (Constant torque mode)
The output voltage of the inverter is in direct proportion to frequency, which is applicable to
most loads as shown in the line of Fig. 6-2.
1 Square (Quadratic torque mode)
The output voltage of the inverter is in conic to frequency, which is applicable to fans, water
pumps and loads so the like, as shown in the curve of Fig. 6-2.
Acceleration TimeAcceleration Time Deceleration TimeDeceleration Time
0
1
Linear acceleration /deceleration
The output frequency increases or decreases in accordance with constant slope.
S curve acceleration/deceleration
To reduce noise and vibration of the mechanical system, DO change the output frequency
slowly and gradually when the acceleration/deceleration begins or ends, as shown in Fig. 6-3.
0 Linear acceleration /deceleration
The output frequency increases or decreases in accordance with constant slope.
1 S curve acceleration/deceleration
To reduce noise and vibration of the mechanical system, DO change the output frequency
slowly and gradually when the acceleration/deceleration begins or ends, as shown in Fig. 6-3.
F014 Setting Range:0 1 Factory Default Value: 0F014 Setting Range:0 1 Factory Default Value: 0
Fig. 6-3 Diagram of Acceleration/Deceleration ModesFig. 6-3 Diagram of Acceleration/Deceleration Modes
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Selection of operation control mode
Selection of motor rotating direction
Maximum Output Frequency
Selection of V/F Curve Modes
Selection of acceleration/deceleration manner
Jogging operation begins when setting the start method F23=0 and
stops when setting the stop method F029=0.
JOG control can be performed by the operator panel, control
terminals and COM ports.
Propriety is always given to JOG frequency operation when
pressing the JOG key in any running state.
Jogging operation begins when setting the start method F23=0 and
stops when setting the stop method F029=0.
JOG control can be performed by the operator panel, control
terminals and COM ports.
Propriety is always given to JOG frequency operation when
pressing the JOG key in any running state.
F020 Setting Range:0.00 50.00Hz Factory Default Value:10.00HzF020 Setting Range:0.00 50.00Hz Factory Default Value:10.00Hz
F021 Setting Range:0.1 3600.0S Factory Default Value:10.0SF021 Setting Range:0.1 3600.0S Factory Default Value:10.0S
F022 Setting Range:0.1 3600.0S Factory Default Value:10.0SF022 Setting Range:0.1 3600.0S Factory Default Value:10.0S
ff11
timetime
tt11 tt22 tt33
F020~F022 are relevant
parameters set for jogging
operation, as shown in Fig. 6-6, in
which t1 indicates the actual JOG
acceleration time, t2 indicates
the JOG time, t3 indicates the
actual JOG deceleration time and
f1 indicates the JOG running
frequency.
F020~F022 are relevant
parameters set for jogging
operation, as shown in Fig. 6-6, in
which t1 indicates the actual JOG
acceleration time, t2 indicates
the JOG time, t3 indicates the
actual JOG deceleration time and
f1 indicates the JOG running
frequency.Fig. 6-6 Diagram of Acceleration/Deceleration TimeFig. 6-6 Diagram of Acceleration/Deceleration Time
F023 Setting Range: 0 2 Factory Default Value: 0Selection of starting modesF023 Selection of starting modes Setting Range: 0 2 Factory Default Value: 0
0 Start at starting frequency
The inverter starts at a certain initial frequency, which is the starting frequency (F024).
1 Braking before starting
DC braking energy (defined in F026~F027) is given by the inverter to the loaded motor
before starting the motor at the starting frequency.
2 Start in the mode of rotation speed tracking
Track the motor' s rotation speed and direction automatically. Then take the tracked speed
as its starting speed and run to the set frequency according to the acceleration and
deceleration time.
0 Start at starting frequency
The inverter starts at a certain initial frequency, which is the starting frequency (F024).
1 Braking before starting
DC braking energy (defined in F026~F027) is given by the inverter to the loaded motor
before starting the motor at the starting frequency.
2 Start in the mode of rotation speed tracking
Track the motor' s rotation speed and direction automatically. Then take the tracked speed
as its starting speed and run to the set frequency according to the acceleration and
deceleration time.
tt22 tt11
f f 22
ItmeItme
F015 Setting Range:0.1 6000.0S Factory Default Value: F015 Setting Range:0.1 6000.0S Factory Default Value:
F016 Setting Range:0.1 6000.0S Factory Default Value: F016 Setting Range:0.1 6000.0S Factory Default Value:
Acceleration time refers to the period during
which the output frequency of the inverter is
accelerated from 0Hz to basic frequency, as
shown in t1 of Fig. 6-4.
Deceleration time refers to the period during
which the output frequency of the inverter is
decelerated from basic frequency to 0Hz, as
shown in t2 of Fig. 6-4.
Acceleration time refers to the period during
which the output frequency of the inverter is
accelerated from 0Hz to basic frequency, as
shown in t1 of Fig. 6-4.
Deceleration time refers to the period during
which the output frequency of the inverter is
decelerated from basic frequency to 0Hz, as
shown in t2 of Fig. 6-4. Fig. 6-4 Diagram of Acceleration/Deceleration TimeFig. 6-4 Diagram of Acceleration/Deceleration Time
F017 Setting Range:F010 Factory Default Value:50.00HzF017 Setting Range:F010 Factory Default Value:50.00Hz
F018 Setting Range:0.00Hz Factory Default Value:0.00HzF018 Setting Range:0.00Hz Factory Default Value:0.00Hz
When running at programmable multistage speed, the
acceleration/deceleration time 1 participates in running as the first stage
acceleration and deceleration time.
When running at programmable multistage speed, the
acceleration/deceleration time 1 participates in running as the first stage
acceleration and deceleration time.
The upper limit of frequency refers to the
allowable maximum output frequency of the
inverter, as shown in f3 of Fig. 6-5.
The lower limit of frequency refers to the
allowable minimum output frequency of the
inverter, as shown in f1 of Fig. 6-5.
During actual running, if the set frequency is
smaller than the lower limit of frequency, the
inverter will reduce the value of output frequency
relevantly. When it reaches the lower limit of
frequency, the inverter will decide its steady state
output according to the running frequency set by
the lower limit of frequency.
The upper limit of frequency refers to the
allowable maximum output frequency of the
inverter, as shown in f3 of Fig. 6-5.
The lower limit of frequency refers to the
allowable minimum output frequency of the
inverter, as shown in f1 of Fig. 6-5.
During actual running, if the set frequency is
smaller than the lower limit of frequency, the
inverter will reduce the value of output frequency
relevantly. When it reaches the lower limit of
frequency, the inverter will decide its steady state
output according to the running frequency set by
the lower limit of frequency.
VVmaxmax
ff11 ff22 ff44
ff33
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Acceleration Time 1
Deceleration Time 1
Upper limit of
frequency
Upper limit of
frequency
Lower limit of frequency
Maximum output frequency
Lower limit of frequency
JOG operation frequency
JOG acceleration time
JOG deceleration time
F029 Setting Range:0 1 Factory Default Value: 0Selection of halt modeF029Selection of halt mode Setting Range:0 1 Factory Default Value: 0
This indicates the time interval between FRD and REV when the inverter transfers from
forward running to 0Hz then to reverse running; or from reverse running to 0Hz then to
forward running, as shown in Fig. 6-9.
This indicates the time interval between FRD and REV when the inverter transfers from
forward running to 0Hz then to reverse running; or from reverse running to 0Hz then to
forward running, as shown in Fig. 6-9.
[[F028F028]]
F028 Setting Range:0.0 10.0S Factory Default Value:2.0SFRD/REV Dead TimeF028FRD/REV Dead Time Setting Range:0.0 10.0S Factory Default Value:2.0S
0
I
1
Decelerating Stop
When stop command is received, the inverter will drop off output frequency in
accordance with set decelerating mode and decelerating time till the frequency falls to zero
and stop.
Free stop
Once stop command is received, the inverter will discard output immediately and the load
will stop freely in accordance with the rule of mechanical inertia.
0 Decelerating Stop
IWhen stop command is received, the inverter will drop off output frequency in
accordance with set decelerating mode and decelerating time till the frequency falls to zero
and stop.
1 Free stop
Once stop command is received, the inverter will discard output immediately and the load
will stop freely in accordance with the rule of mechanical inertia.
If decelerating stop (F029=0) is selected, the inverter will discard output
upon receiving of stop command. When the motor decelerates to shutdown
DC braking starting frequency (F030) (which indicates the inverter's
starting frequency when the motor is shutdown by DC braking), the inverter
will stop by braking according to shutdown DC braking voltage (which
indicates the inverter's voltage when the motor is shutdown by DC braking)
set by F031 and shutdown DC braking time (which indicates a specified
period of time used to stop the motor by DC braking) set by F032.
If decelerating stop (F029=0) is selected, the inverter will discard output
upon receiving of stop command. When the motor decelerates to
(F030) (which indicates the inverter's
starting frequency when the motor is shutdown by DC braking), the inverter
will stop by braking according to (which
indicates the inverter's voltage when the motor is shutdown by DC braking)
set by F031 and (which indicates a specified
period of time used to stop the motor by DC braking) set by F032.
shutdown
DC braking starting frequency
shutdown DC braking voltage
shutdown DC braking time
F027 Setting Range:0.0 20.0S Factory Default Value:0.0SStarting-up DC braking periodF027 Starting-up DC braking period Setting Range:0.0 20.0S Factory Default Value:0.0S
F024 Setting Range:0.00 20.00Hz Factory Default Value:0.00HzF024 Setting Range:0.00 20.00Hz Factory Default Value:0.00Hz
F025 Setting Range:0.0 30.0S Factory Default Value:0.0SF025 Setting Range:0.0 30.0S Factory Default Value:0.0S
Starting frequency is the initial frequency when the inverter starts, as shown in fs of Fig.
6-7. To ensure enough starting torque, the starting frequency should be set properly.
Starting frequency maintaining time refers to the time kept by starting frequency when the
inverter starts running, as shown in t1 of Fig. 6-7.
Starting frequency is the initial frequency when the inverter starts, as shown in fs of Fig.
6-7. To ensure enough starting torque, the starting frequency should be set properly.
Starting frequency maintaining time refers to the time kept by starting frequency when the
inverter starts running, as shown in t1 of Fig. 6-7.
tt11
ffmaxmax
ffss
[[F027F027]]
Fig. 6-7 Diagram of Starting Frequency and Holding TimeFig. 6-7 Diagram of Starting Frequency and Holding Time
Fig. 6-8 Diagram of Starting DC Braking timeFig. 6-8 Diagram of Starting DC Braking time
DO take into the consideration of loads before generating the DC
braking voltage and deciding the braking time, for over-voltage may
result in current trip. As for high-speed inertia load, it is not advisable
to start the machine by DC braking.
DO take into the consideration of loads before generating the DC
braking voltage and deciding the braking time, for over-voltage may
result in current trip. As for high-speed inertia load, it is not advisable
to start the machine by DC braking.
F026 Setting Range:0. 20% Factory Default Value: 0%F026 Setting Range:0. 20% Factory Default Value: 0%
F026 and F027 are valid only when selecting the mode braking before starting
(F023=1), as shown in Fig. 6-8.
F026 and F027 are valid only when selecting the mode braking before starting
(F023=1), as shown in Fig. 6-8.
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Starting frequency maintaining timeStarting frequency maintaining time
Starting DC braking voltage
(indicates the inverter's voltage when the motor is shutdown by DC braking)
( specified period of time used to start the motor by DC braking)
F037 Setting Range: 0.01 100.0 Factory Default Value:1.00F037 Setting Range: 0.01 100.0 Factory Default Value:1.00
F038 Setting Range: 0.001 10.00 Factory Default Value:1.000F038 Setting Range: 0.001 10.00 Factory Default Value:1.000
F037 is used to correct the display error of linear speed. It has no effect on actual rotation
speed.
F038 is used to correct the display error of PID feed or feedback flow under closed-loop
control. It has no effect on closed-loop PID regulation.
F037 is used to correct the display error of linear speed. It has no effect on actual rotation
speed.
F038 is used to correct the display error of PID feed or feedback flow under closed-loop
control. It has no effect on closed-loop PID regulation.
0
1
This function is used to set the function of REV/JOG key on operator panel.
Select 0 to set REV function.
Select 1 to set JOG function.
This function is used to set the function of REV/JOG key on operator panel.
0 Select 0 to set REV function.
1 Select 1 to set JOG function.
F039 Setting Range: 0 1 Factory Default Value: 1F039 Setting Range: 0 1 Factory Default Value: 1
F040 Setting Range: 0 2 Factory Default Value: 0F040 Setting Range: 0 2 Factory Default Value: 0
0
1
This function is used to select three operation modes of the inverter controlled by external
control terminals.
Two-wire control mode 1, as shown in Table 6-3 and Fig. 6-10.
1: Two-wire control mode 2, as shown in Table 6-3 and Fig. 6-10.
This function is used to select three operation modes of the inverter controlled by external
control terminals.
0 Two-wire control mode 1, as shown in Table 6-3 and Fig. 6-10.
1 1: Two-wire control mode 2, as shown in Table 6-3 and Fig. 6-10.
perating Instructionperating Instruction
Note: ON indicates switch on; OFF indicates switch off.Note: ON indicates switch on; OFF indicates switch off.
K1K1
K2K2
FWDFWD
REVREV
COMCOM
witch statuswitch status
F030 Setting Range: 0.00 20.00Hz Factory Default Value:3.00Hz F030 Setting Range: 0.00 20.00Hz Factory Default Value:3.00Hz
F031 Setting Range: 0 20% Factory Default Value: 0%F031 Setting Range: 0 20% Factory Default Value: 0%
F032 Setting Range: 0.0 30.0S Factory Default Value:0.0SF032 Setting Range: 0.0 30.0S Factory Default Value:0.0S
F030 indicates the frequency at which DC braking starts working during
decelerating stop of the inverter.
F031 indicates the percentage of the inverter's output voltage when the motor
is shutdown by DC braking to the inverter's rated output voltage.
F032 indicates the holding time of the motor's shutdown by DC braking.
F030 indicates the frequency at which DC braking starts working during
decelerating stop of the inverter.
F031 indicates the percentage of the inverter's output voltage when the motor
is shutdown by DC braking to the inverter's rated output voltage.
F032 indicates the holding time of the motor's shutdown by DC braking.
F034 Setting Range: 0 13 Factory Default Value: 0F034 Setting Range: 0 13 Factory Default Value: 0
Oversetting of the inverter's voltage when the motor is shutdown
by DC braking may easily lead to inverter tripping. DO increase the
voltage bit by bit.
If the specified period of time used to stop the motor by DC
braking is set to 0.0s, then no DC braking will proceed.
Oversetting of the inverter's voltage when the motor is shutdown
by DC braking may easily lead to inverter tripping. DO increase the
voltage bit by bit.
If the specified period of time used to stop the motor by DC
braking is set to 0.0s, then no DC braking will proceed.
This function is used to set the display items when the inverter is just powered on.
Motor rotating speed
Power module temperature
Cumulative time of current running (Hours) Input terminal status
This function is used to set the display items when the inverter is just powered on.
Motor rotating speed
Power module temperature
Cumulative time of current running (Hours) Input terminal status
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Shutdown DC braking starting frequency
Shutdown DC braking voltage
Shutdown DC braking time
Selection of Power On display items
Display coefficient of linear speed
Display coefficient of closed-loop control
Selection of REV/JOG key function
Two-wire/Three-wire operating selection
Two-wire control 1
Two-wire control 2
Operating instruction 1
Operating instruction 2
F041 time2 Setting Range: 0.0 6000.0S Factory Default Value: AccelerationF041 Acceleration time2 Setting Range: 0.0 6000.0S Factory Default Value:
F042 time2 Setting Range: 0.0 6000.0S Factory Default Value:DecelerationF042 Deceleration time2 Setting Range: 0.0 6000.0S Factory Default Value:
2
Three-wire control mode
Fig. 6-11 is a three-wire control diagram, in
which SK1 represents FRD switch, SK2
represents stop switch and Xn represents a
three-wire operating control terminal that can be
any one of the multi-function terminal X1~X6
(refer to parameter F111~F116) by selecting
13
2 Three-wire control mode
Fig. 6-11 is a three-wire control diagram, in
which SK1 represents FRD switch, SK2
represents stop switch and Xn represents a
three-wire operating control terminal that can be
any one of the multi-function terminal X1~X6
(refer to parameter F111~F116) by selecting
13
SK1SK1FWDFWD
SK2SK2
SK3 SK3 REVREV COMCOM
XXnn
F041 and F042 refer to acceleration/deceleration time controlled by
the inverter external terminals by selecting 4 of the multifunction
terminal X1~X6 F111~F116 .
F041 and F042 refer to acceleration/deceleration time controlled by
the inverter external terminals by selecting 4 of the multifunction
terminal X1~X6 F111~F116 .
The acceleration/deceleration time of multi-speed operation and
jog operation is out of the control of external input terminals and can be
set only by its own parameters.
The acceleration/deceleration time of multi-speed operation and
jog operation is out of the control of external input terminals and can be
set only by its own parameters.
F045 Setting Range: 0 1 Factory Default Value: 0F045 Setting Range: 0 1 Factory Default Value: 0
1 Forbidden 1 Allowable
When selecting automatic energy-saving operation, the inverter will automatically
regulate the motor's output voltage by detecting the load current, so as to get minimum
product (electric power ) of voltage and current and realize energy saving.
When selecting automatic energy-saving operation, the inverter will automatically
regulate the motor's output voltage by detecting the load current, so as to get minimum
product (electric power ) of voltage and current and realize energy saving.
1 Forbidden 1 Allowable
This function is applicable to loads like fans, water pumps and etc.
Automatic energy-saving operation is invalid during acceleration
and deceleration.
This function is applicable to loads like fans, water pumps and etc.
Automatic energy-saving operation is invalid during acceleration
and deceleration.
F046 Setting Range: 0.0 20.0% Factory Default Value:0.0%F046 Setting Range: 0.0 20.0% Factory Default Value:0.0%
During actual rotation, a motor's slip is influenced by variation in load torque, which
causes deviation of actual speed from the expected value. With slip compensation function,
the inverter's output power can be adjusted automatically with load torque fluctuation of the
motor, which can compensate off-speed arising from load fluctuation of the motor and thus
improve accuracy of speed.
This parameter is the percentage of slip compensation to rated slip.
During actual rotation, a motor's slip is influenced by variation in load torque, which
causes deviation of actual speed from the expected value. With slip compensation function,
the inverter's output power can be adjusted automatically with load torque fluctuation of the
motor, which can compensate off-speed arising from load fluctuation of the motor and thus
improve accuracy of speed.
This parameter is the percentage of slip compensation to rated slip.
F047 Setting Range: 0 1 Factory Default Value: 0F047 Setting Range: 0 1 Factory Default Value: 0
F048 Setting Range: 0 30% Factory Default Value:F048 Setting Range: 0 30% Factory Default Value:
1 Forbidden 1 Allowable
AVR means automatic voltage regulation. When deviation occurs between input voltage and rated input voltage of the inverter, this function is applied to stabilize the output voltage of the inverter through auto regulation of duty factor of PWM.
This function is invalid in case the output command voltage is higher than the input power supply voltage.
1 Forbidden 1 Allowable AVR means automatic voltage regulation. When deviation occurs between input voltage and rated input voltage of the inverter, this function is applied to stabilize the output voltage of the inverter through auto regulation of duty factor of PWM. This function is invalid in case the output command voltage is higher than the input power supply voltage.
Excitation voltage falls in the zone of low frequency rotation. So, it is necessary to
compensate excitation current of the motor and enhance the torque in the state of low
frequency rotation (improve V/F characteristic), as shown in Fig.6-12.
Excitation voltage falls in the zone of low frequency rotation. So, it is necessary to
compensate excitation current of the motor and enhance the torque in the state of low
frequency rotation (improve V/F characteristic), as shown in Fig.6-12.
The Vb in the figure refers to manual torque lifting voltage; Fn refers to
rated frequency of the inverter.
The Vb in the figure refers to manual torque lifting voltage; Fn refers to
rated frequency of the inverter.
characteristiccharacteristic
torque characteristictorque characteristic
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Determined in accordance with specifications.Determined in accordance with specifications.
Selection of automatic energy-saving operation
AVR function selection
Determined in accordance with specifications.
F049 Setting Range: 1.0 13KHz Factory Default Value:Carrier frequencyF049 Carrier frequency Setting Range: 1.0 13KHz Factory Default Value:
Too high torque lifting may result in over-current protection of the
inverter which may lead to failure starting of the motor. When this
occurs, the set value shall be decreased properly.
Too high torque lifting may result in over-current protection of the
inverter which may lead to failure starting of the motor. When this
occurs, the set value shall be decreased properly.
Heat dissipation will be less effective when a motor runs at a
low frequency for a long period. Oversetting of torque lifting value in
this case may speedup this phenomena and lead to burnout of the
motor. DO keep in mind to take a forced method to release heat from
the exterior of motor or perform derating before use.
Heat dissipation will be less effective when a motor runs at a
low frequency for a long period. Oversetting of torque lifting value in
this case may speedup this phenomena and lead to burnout of the
motor. DO keep in mind to take a forced method to release heat from
the exterior of motor or perform derating before use.
This function is used to set the carrier frequency of the inverter's output PWM wave and should be properly regulated. The maximum value of carrier frequency is determined in accordance with power specifications. Refer to Fig. 6-13 for details on carrier frequency value, electromagnetic noise, leakage current and heating conditions.
This function is used to set the carrier frequency of the inverter's output PWM wave and should be properly regulated. The maximum value of carrier frequency is determined in accordance with power specifications. Refer to Fig. 6-13 for details on carrier frequency value, electromagnetic noise, leakage current and heating conditions.
Due to rich ultra harmonics existed in output current, under setting of carrier frequency will result in distortion of the waveform of output current, which may cause larger noise of motor, but less loss and lower temperature rise instead.
Increasing the set value of carrier frequency can reduce noise of the motor, but the inverter's temperature will rise due to greater loss of power elements. If the carrier frequency value is higher than factory default setting, then the inverter shall be derated before use.
Due to rich ultra harmonics existed in output current, under setting of carrier frequency will result in distortion of the waveform of output current, which may cause larger noise of motor, but less loss and lower temperature rise instead.
Increasing the set value of carrier frequency can reduce noise of the motor, but the inverter's temperature will rise due to greater loss of power elements. If the carrier frequency value is higher than factory default setting, then the inverter shall be derated before use.
F051 Setting Range:0.00 10.00Hz Factory Default Value:0.00HzF051 Setting Range:0.00 10.00Hz Factory Default Value:0.00Hz
F052 Setting Range: Factory Default Value:0.00HzLeap frequency 2F052 Leap frequency 2 Setting Range: Factory Default Value:0.00Hz
F053 Setting Range:0.00 10.00Hz Factory Default Value:0.00HzF053 Setting Range:0.00 10.00Hz Factory Default Value:0.00Hz
The purpose of F050~F053 setting is to avoid point of resonant frequency of
mechanical load so that the second point of leap frequency of the inverter can be set.
If the leap range is set to 0, then no leap function performs at the
corresponding points of leap frequency.
The inverter's output frequency can act leap operation nearby some frequency
points.
The purpose of F050~F053 setting is to avoid point of resonant frequency of
mechanical load so that the second point of leap frequency of the inverter can be set.
If the leap range is set to 0, then no leap function performs at the
corresponding points of leap frequency.
The inverter's output frequency can act leap operation nearby some frequency
points.
F050 Setting Range: Factory Default Value:0.00HzLeap frequency 1F050 Leap frequency 1 Setting Range: Factory Default Value:0.00Hz
During accelerating and decelerating running, the inverter can
not skip leap frequency.
Do not set two leap frequency ranges overlaid or inlaid.
During accelerating and decelerating running, the inverter can
not skip leap frequency.
Do not set two leap frequency ranges overlaid or inlaid.
Leap frequency 2Leap frequency 2
Leap frequency 1Leap frequency 1
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Determined in accordance with specifications.
Range of leap frequency 1
Range of leap frequency 2
Lower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequency
Range of leap frequency 2
Range of leap frequency 1
F054 Setting Range:10.0 400.0Hz Factory Default Value:50.00HzF054 Setting Range:10.0 400.0Hz Factory Default Value:50.00Hz
F055 Setting Range:0 1 Factory Default Value: 0F055 Setting Range:0 1 Factory Default Value: 0
F056 Setting Range:0.0 20.0S Factory Default Value:1.0SWait time for retryF056 Wait time for retry Setting Range:0.0 20.0S Factory Default Value:1.0S
This function is applied to set corresponding frequency of acceleration/deceleration time.This function is applied to set corresponding frequency of acceleration/deceleration time.
F055 0
1
This function decides whether the inverter can start running automatically or not and the wait time
for auto running under different modes of control when the inverter is electrified after power failure.
Select 0 (disable), the inverter will not run automatically when it is energized after power
failure.
Select 1 (enable), if starting criteria permits, the inverter will restart automatically by way of
rotation speed tracing in a time set by F056 when it is energized after power failure.
During the period of waiting for restarting, it is invalid to input any operating instruction. For
example, the inverter will automatically abort restarting by rotation speed tracing and restore to the
status of normal stop is stop command is given during this period.
Whether the inverter will run automatically or not is co-decided by this set of parameter setting, the
running status at the moment of power failure and the control command at the moment of power on.
F055 0
1
This function decides whether the inverter can start running automatically or not and the wait time
for auto running under different modes of control when the inverter is electrified after power failure.
Select 0 (disable), the inverter will not run automatically when it is energized after power
failure.
Select 1 (enable), if starting criteria permits, the inverter will restart automatically by way of
rotation speed tracing in a time set by F056 when it is energized after power failure.
During the period of waiting for restarting, it is invalid to input any operating instruction. For
example, the inverter will automatically abort restarting by rotation speed tracing and restore to the
status of normal stop is stop command is given during this period.
Whether the inverter will run automatically or not is co-decided by this set of parameter setting, the
running status at the moment of power failure and the control command at the moment of power on.
If the Retry Mode which means restart after instantaneous power
failure is enabled, an unanticipated sudden restart will happen once
the equipment is energized, which may result in heavy loss of property,
serious injury or death to personnel in some cases (i.e., the inverter
restarts due to disconnection of input power supply undone before
performing a maintenance of mechanical load). DO put a warning sign
in an eye-catching place before the equipment to avoid sudden restart
of the equipment.
If the Retry Mode which means restart after instantaneous power
failure is enabled, an unanticipated sudden restart will happen once
the equipment is energized, which may result in heavy loss of property,
serious injury or death to personnel in some cases (i.e., the inverter
restarts due to disconnection of input power supply undone before
performing a maintenance of mechanical load). DO put a warning sign
in an eye-catching place before the equipment to avoid sudden restart
of the equipment.
YY
FDT lagged value FDT lagged value
YY
F057 Setting Range:0.00 15.00Hz Factory Default Value:5.00HzF057 Setting Range:0.00 15.00Hz Factory Default Value:5.00Hz
If the inverter's output frequency is within the range of positive/negative checkout range of
the set frequency, the selected output terminal will output valid signal (low power level), as
shown in Fig. 6-15.
If the inverter's output frequency is within the range of positive/negative checkout range of
the set frequency, the selected output terminal will output valid signal (low power level), as
shown in Fig. 6-15.
F058 Setting Range: Factory Default Value:10.00HzFDT levelF058 FDT level Setting Range: Factory Default Value:10.00Hz
F059 Setting Range:0.00 30.00Hz Factory Default Value:1.00HzFDT lagged valueF059 FDT lagged value Setting Range:0.00 30.00Hz Factory Default Value:1.00Hz
This set of parameters is applied to set the frequency detection level. If the output frequency
rises and exceeds the set value of FDT, then open collector signal (low power level) will be
output; if the output frequency falls to the FDT removal of power level, then invalid signal
(high resistance) will be output, as shown in Fig. 6-16.
This set of parameters is applied to set the frequency detection level. If the output frequency
rises and exceeds the set value of FDT, then open collector signal (low power level) will be
output; if the output frequency falls to the FDT removal of power level, then invalid signal
(high resistance) will be output, as shown in Fig. 6-16.
Fig. 6-15 Frequency Arrival Checkout DiagramFig. 6-15 Frequency Arrival Checkout Diagram
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Reference frequency of acceleration/deceleration time
Selection of retry mode
Frequency Arrival Checkout Range (FAR)
0.00Hz~upper limit of frequency
(restart after instantaneous power failure)
F066 Setting Range:0.0mA F067 Factory Default Value:4.0mAF066 Setting Range:0.0mA F067 Factory Default Value:4.0mA
F067 Setting Range:F066 20.0mA Factory Default Value:20.0mAF067 Setting Range:F066 20.0mA Factory Default Value:20.0mA
This function is used to set the bipolarity control of input analog signal.
Bipolarity control indicates the inverter's output phase sequence or the motor's diversion is
decided by the polarity of input analog signal. At this moment, other diversion orders are
neglected by the inverter. If the analog signal is higher than the percentage of zero offset and
the frequency biases positive/negative, then positive/negative phase sequence will be output
and the motor forwards/reverses accordingly. If the analog signal is lower than the percentage
of zero offset and the frequency biases negative/positive, then negative/positive phase
sequence will be output and the motor reverses/forwards accordingly.
Bipolarity control function is valid only if the setting mode of frequency selects analog
signal input (F009=3 or 4) and the frequency setting value is decided by the input analog
signal at this point.
The correlation between analog input signal and set frequency with different settings is as
shown in Fig. 6-18 & 6-19.
This function is used to set the bipolarity control of input analog signal.
Bipolarity control indicates the inverter's output phase sequence or the motor's diversion is
decided by the polarity of input analog signal. At this moment, other diversion orders are
neglected by the inverter. If the analog signal is higher than the percentage of zero offset and
the frequency biases positive/negative, then positive/negative phase sequence will be output
and the motor forwards/reverses accordingly. If the analog signal is lower than the percentage
of zero offset and the frequency biases negative/positive, then negative/positive phase
sequence will be output and the motor reverses/forwards accordingly.
Bipolarity control function is valid only if the setting mode of frequency selects analog
signal input (F009=3 or 4) and the frequency setting value is decided by the input analog
signal at this point.
The correlation between analog input signal and set frequency with different settings is as
shown in Fig. 6-18 & 6-19.
F068 Setting Range:0 100% Factory Default Value:0%F068 Setting Range:0 100% Factory Default Value:0%
F069 Setting Range:0 1 Factory Default Value:0F069 Setting Range:0 1 Factory Default Value:0
F070 Setting Range:0 1 Factory Default Value:0F070 Setting Range:0 1 Factory Default Value:0
Fig.6-19 F068=50%
F069=(0) F070=0(1)
Bipolarity ControlFig.6-19 Bipolarity ControlF068=50%
F069=(0) F070=0(1)
F060 Setting Range:20 110% Factory Default Value:100%Overload Pre-alarm LevelF060 Overload Pre-alarm Level Setting Range:20 110% Factory Default Value:100%
F061 Setting Range:0.0 15.0S Factory Default Value:1.0SF061 Setting Range:0.0 15.0S Factory Default Value:1.0S
Overload pre-alarm level defines the current threshold of overload pre-alarm action. Its
setting range is the percentage in respect to rated current. Generally, the overload pre-alarm
level should be set lower than overload protection level.
If the output current reaches the overload pre-alarm level and its durative level exceeds the
set time of overload pre-alarm action, then overload pre-alarm acts, as shown in Fig. 6-17.
Overload pre-alarm level defines the current threshold of overload pre-alarm action. Its
setting range is the percentage in respect to rated current. Generally, the overload pre-alarm
level should be set lower than overload protection level.
If the output current reaches the overload pre-alarm level and its durative level exceeds the
set time of overload pre-alarm action, then overload pre-alarm acts, as shown in Fig. 6-17.
Fig. 6-17 Diagram of Overload Pre-alarm ActionFig. 6-17 Diagram of Overload Pre-alarm Action
F064 Setting Range:0.0V F065 Factory Default Value:0.0VF064 Setting Range:0.0V F065 Factory Default Value:0.0V
F065 Setting Range:F064 10.0V Factory Default Value:10.0VF065 Setting Range:F064 10.0V Factory Default Value:10.0V
F064 and F065 are applied to set the maximum and minimum values of external
analog input voltage V, which should be set in the light of actual conditions of input
signals.
F064 and F065 are applied to set the maximum and minimum values of external
analog input voltage V, which should be set in the light of actual conditions of input
signals.
YY
[[ ]]
[[ ]]
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Overload Pre-alarm Action Time
Lower limit of analog voltage (V) input
limit of analog voltage (V) input
Lower limit of analog current (I) input
Lower limit of analog current (I) input
Bipolarity zero offset of analog input
Corresponding frequency biasing direction of the lower limit of analog inputBiasing direction of the frequency corresponding to the upper limit of analog input
ffmamaxx
ffminmin
IIminmin VVminmin
IImaxmax VVmaxmax
II
VV
ffmaxmax
ffminmin
IIminmin VVminmin
IImaxmax VVmaxmax
II
VV
If bipolarity control is selected, the parameter F068 must be greater than 0%, or it is invalid. The
default setting is 0% which means invalid bipolarity control at this point. If F068 is greater than 0%, then
the analog input signal within F064 F066 F065 F067 *F068 F065 F067 will be linear with
the frequency within F071 F072, and the output phase sequence of the inverter will be decided by F069
or F070.
If setting F069 and F070 to 0 and 1 separately, then the analog signal within F064 F066
F065 F067 *F068 proceeds forward and the frequency fluctuates within F071 0.00Hz; while the
analog signal within F065 F067 *F068 F065 F067 proceeds reverse and the frequency fluctuates
within 0.00Hz to F072. If setting F069 and F070 to 1 and 0 separately, the above action will
reverse.
If setting F069 and F070 to 0 , 0 or 1 , 1 , then the motor proceeds forward or reverse,
but the frequency still fluctuates with analog input signal and the frequency change manner remains the
same as the one that proceeds forward and reverse.
If bipolarity control is selected, the parameter F068 must be greater than 0%, or it is invalid. The
default setting is 0% which means invalid bipolarity control at this point. If F068 is greater than 0%, then
the analog input signal within F064 F066 F065 F067 *F068 F065 F067 will be linear with
the frequency within F071 F072, and the output phase sequence of the inverter will be decided by F069
or F070.
If setting F069 and F070 to 0 and 1 separately, then the analog signal within F064 F066
F065 F067 *F068 proceeds forward and the frequency fluctuates within F071 0.00Hz; while the
analog signal within F065 F067 *F068 F065 F067 proceeds reverse and the frequency fluctuates
within 0.00Hz to F072. If setting F069 and F070 to 1 and 0 separately, the above action will
reverse.
If setting F069 and F070 to 0 , 0 or 1 , 1 , then the motor proceeds forward or reverse,
but the frequency still fluctuates with analog input signal and the frequency change manner remains the
same as the one that proceeds forward and reverse.
F071 Setting Range: Factory Default Value:0.00HzF071 Setting Range: Factory Default Value:0.00Hz
F072 Setting Range: Factory Default Value:50.00HzF072 Setting Range: Factory Default Value:50.00Hz
This set of parameters is used to set the correlation between external analog input quantity
and the set frequency. The relationship between set frequency and frequency setting signal
after treatment of filtering and gain is shown in Fig. 6-20. These two kinds of signals can
realize the characteristics of direct action and reaction separately. fmax and fmin in
this figure refer to the frequency corresponding to the upper limit of input and the lower limit of
input respectively.
This set of parameters is used to set the correlation between external analog input quantity
and the set frequency. The relationship between set frequency and frequency setting signal
after treatment of filtering and gain is shown in Fig. 6-20. These two kinds of signals can
realize the characteristics of direct action and reaction separately. fmax and fmin in
this figure refer to the frequency corresponding to the upper limit of input and the lower limit of
input respectively.
uantity against Set Frequencyuantity against Set Frequency
F073 Setting Range:0.1 5.0S Factory Default Value:0.5SF073 Setting Range:0.1 5.0S Factory Default Value:0.5S
F074 Analog output (AM) Setting Range:0 4 Factory Default Value: 0F074 Analog output (AM) Setting Range:0 4 Factory Default Value: 0
F075 Analog output (AM) gain Setting Range:50 200% Factory Default Value:100%F075 Analog output (AM) gain Setting Range:50 200% Factory Default Value:100%
This parameter is used to regulate the delay period of analog input signal.This parameter is used to regulate the delay period of analog input signal.
This function is used to indicate the content of the output signal of analog output end (AM)
and the value of output voltage, as shown in Fig. 6-21 and Fig. 6-22
This function is used to indicate the content of the output signal of analog output end (AM)
and the value of output voltage, as shown in Fig. 6-21 and Fig. 6-22
Factory Default Value
0
1
2
3 Output Voltage
4
Running frequency
Motor rotation speed
Output current
PID feedback quantity
Factory Default Value
0Running frequency
1 Motor rotation speed
2 Output current
3 Output Voltage
4 PID feedback quantity
F076 Setting Range: 0.00 3.00V Factory Default Value:2.00VF076 Setting Range: 0.00 3.00V Factory Default Value:2.00V
Due to diversity of device parameters and variance in operating ambient, zero drift exists in the
output voltage of analog output AM terminal. This parameter is used to compensate the influence
arising from zero drift. E.g., if the zero offset of AM output is 0.20V, just set this parameter to -
0.20V to make up for it. The detail compensation value should be set in the light of actual
conditions.
Due to diversity of device parameters and variance in operating ambient, zero drift exists in the
output voltage of analog output AM terminal. This parameter is used to compensate the influence
arising from zero drift. E.g., if the zero offset of AM output is 0.20V, just set this parameter to -
0.20V to make up for it. The detail compensation value should be set in the light of actual
conditions.
Factory Default Value
0:
1
2
3 Output Voltage
4
Running frequency
Motor rotation speed
Output current
PID feedback quantity
Factory Default Value
0:Running frequency
1 Motor rotation speed
2 Output current
3 Output Voltage
4 PID feedback quantity
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Corresponding frequency of minimum analog input
Corresponding frequency of maximum analog input
0.00Hz~upper limit of frequency
0.00Hz~upper limit of frequency
Analog input signal delay period
Analog Meter output (AM) offset
TT11 TT22 TT33 TT44 TT55 TT66 TT77
aa11
aa22
aa33
aa44
aa55 ff11
ff22
ff33
ff44
ff55
ff77 aa66
dd33
dd55
dd77
f1 f7 in this figure refers to running frequency at stage 1 7 separately.
T1 T7 refers to running time at stage 1 7 separately.a1 a6 refers to acceleration time at stage 1 7 separately.d3, d5 and d7 refer to the deceleration time at stage 3, 5 and 7
separately.
Continuous cyclingThis indicates the multi-speed running of the inverter recycles repeatedly and stops only if stop command is input, as shown in Fig. 6-24.
2
f1 f7 in this figure refers to running frequency at stage 1 7 separately. T1 T7 refers to running time at stage 1 7 separately. a1 a6 refers to acceleration time at stage 1 7 separately. d3, d5 and d7 refer to the deceleration time at stage 3, 5 and 7 separately.
2 Continuous cycling This indicates the multi-speed running of the inverter recycles repeatedly and stops only if stop command is input, as shown in Fig. 6-24.
ff66
TT11 TT22 TT33 TT44 TT55 TT66 TT77
aa11
aa22
aa33
aa44
aa55 ff11
ff22
ff33
ff44
ff55
ff77 aa66
dd33
dd55
dd77 ff22
ff11
aa22
dd33
dd11
TT11 TT22
Fig. 6-24 Diagram of Programmable/Multi-speed Continuous Cycling OperationFig. 6-24 Diagram of Programmable/Multi-speed Continuous Cycling Operation
3
Maintaining the ultimate value after singe cycling
After finishing a single cycle, the inverter will run according to the set frequency and
direction of the latest multi-speed running (except stage 0), as shown in Fig. 6-25.
3 Maintaining the ultimate value after singe cycling
After finishing a single cycle, the inverter will run according to the set frequency and
direction of the latest multi-speed running (except stage 0), as shown in Fig. 6-25.
Fig. 6-25 Diagram of maintaining the ultimate value after programmable/multi-speed single Cycling OperationFig. 6-25 Diagram of maintaining the ultimate value after programmable/multi-speed single Cycling Operation
ff66
TT11 TT22 TT33 TT44 TT55 TT66 TT77
aa11
aa22
aa33
aa44
aa55 ff11
ff22
ff33
ff44
ff55
ff77 aa66
dd33
dd55
dd77
[F016][F016]
F077 Setting Range:0 3 Factory Default Value: 0F077 Setting Range:0 3 Factory Default Value: 0
0: +
1: -
2: +
3: -
When F009 selects analog input combined setting (F009=5), this
function is used to select its combined mode.
External voltage V External current I
External voltage V External current I
External current I External voltage V
External current I External voltage V
When F009 selects analog input combined setting (F009=5), this
function is used to select its combined mode.
0:External voltage V+External current I
1:External voltage V-External current I
2:External current I+External voltage V
3:External current I-External voltage V
F080 Setting Range:0 4 Factory Default Value: 0F080 Setting Range:0 4 Factory Default Value: 0
0
1
Non operation
Single cycling
The multi-speed running of the inverter stops automatically after a cycle and starts only
if the run command is given again. E.g., suppose the running time at some stage is 0, then
the inverter will skip to the next stage directly, as shown in Fig. 6-23.
0 Non operation
1 Single cycling
The multi-speed running of the inverter stops automatically after a cycle and starts only
if the run command is given again. E.g., suppose the running time at some stage is 0, then
the inverter will skip to the next stage directly, as shown in Fig. 6-23.
Fig. 6-23 Diagram of Programmable/Multi-speed Single-cycle OperationFig. 6-23 Diagram of Programmable/Multi-speed Single-cycle Operation
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Selection of programmable multi-speed operation
F088 Setting Range:0.0 6000.0S Factory Default Value:20.0SF088 Setting Range:0.0 6000.0S Factory Default Value:20.0S
F089 Setting Range:0 1 Factory Default Value: 0F089 Setting Range:0 1 Factory Default Value: 0
F090 Setting Range:0.0 3600.0S Factory Default Value:20.0SF090 Setting Range:0.0 3600.0S Factory Default Value:20.0S
F088 F090 are used to set the first stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F088 F090 are used to set the first stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F091 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF091 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F092 Setting Range:0 1 Factory Default Value: 0F092 Setting Range:0 1 Factory Default Value: 0
F093 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF093 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F091 F093 are used to set the second stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F091 F093 are used to set the second stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F094 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF094 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F095 Setting Range:0 1 Factory Default Value: 0F095 Setting Range:0 1 Factory Default Value: 0
F096 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF096 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F094 F096 are used to set the third stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F094 F096 are used to set the third stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F097 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF097 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F098 Setting Range:0 1 Factory Default Value: 0F098 Setting Range:0 1 Factory Default Value: 0
F099 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF099 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F097 F099 are used to set the fourth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F097 F099 are used to set the fourth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F100 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF100 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
F101 Setting Range:0 1 Factory Default Value: 0F101 Setting Range:0 1 Factory Default Value: 0
F102 Setting Range:0.0 3600.0S Factory Default Value: 20.0SF102 Setting Range:0.0 3600.0S Factory Default Value: 20.0S
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4
Wobbulation Control
The output frequency of the inverter changes periodically during the preset
accelerating/decelerating time. This function is especially applied to textile and chemical fiber
system in which rotation speed changes due to differential diameter in the font and at the back of
a bobbin, as shown in Fig. 6-26.
4 Wobbulation Control
The output frequency of the inverter changes periodically during the preset
accelerating/decelerating time. This function is especially applied to textile and chemical fiber
system in which rotation speed changes due to differential diameter in the font and at the back of
a bobbin, as shown in Fig. 6-26.
F081 F087 are used to set the frequency of
programmable/multistage speed running. See Fig.
6-24 for details.
F081 F087 are used to set the frequency of
programmable/multistage speed running. See Fig.
6-24 for details.
WW
F081 Setting Range: Factory Default Value:5.00 HzF081 Setting Range: Factory Default Value:5.00 Hz
F082 Setting Range: Factory Default Value:10.00HzF082 Setting Range: Factory Default Value:10.00Hz
F083 Setting Range: Factory Default Value:20.00HzF083 Setting Range: Factory Default Value:20.00Hz
F084 Setting Range: Factory Default Value:30.00HzF084 Setting Range: Factory Default Value:30.00Hz
F085 Setting Range: Factory Default Value:40.00HzF085 Setting Range: Factory Default Value:40.00Hz
F086 Setting Range: Factory Default Value:45.00HzF086 Setting Range: Factory Default Value:45.00Hz
F087 Setting Range: Factory Default Value:50.00HzF087 Setting Range: Factory Default Value:50.00Hz
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
1st-stage speed running frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
Lower limit of frequencyUpper limit of frequencyLower limit of frequencyUpper limit of frequency
2nd-stage speed running frequency
rd3 -stage speed running frequency
rd4 -stage speed running frequency
rd5 -stage speed running frequency
rd6 -stage speed running frequency
rd7 -stage speed running frequency
st1 -stage speed running time
s t1 -stage speed running direction
st1 -stage speed acceleration/deceleration time
st2 -stage speed running time
s t2 -stage speed running direction
st2 -stage speed acceleration/deceleration time
st3 -stage speed running time
s t3 -stage speed running direction
st3 -stage speed acceleration/deceleration time
st4 -stage speed running time
s t4 -stage speed running direction
st4 -stage speed acceleration/deceleration time
st5 -stage speed running time
s t5 -stage speed running direction
st5 -stage speed acceleration/deceleration time
0 No function
1 Selection of multistage speed 1
2 Selection of multistage speed 2
3 Selection of multistage speed 3
The ON/OFF pair selected by multi-speed running at Stage 1 3 can define maximal 7 speed
stages of running. Multi-speed control terminals are selected by the parameters F111 F116. The
multi-speed control of external terminals can be operated together with RUN command. The
multistage speed of terminals is shown in Table 6-4 below.
0 No function
1 Selection of multistage speed 1
2 Selection of multistage speed 2
3 Selection of multistage speed 3
The ON/OFF pair selected by multi-speed running at Stage 1 3 can define maximal 7 speed
stages of running. Multi-speed control terminals are selected by the parameters F111 F116. The
multi-speed control of external terminals can be operated together with RUN command. The
multistage speed of terminals is shown in Table 6-4 below.
Multistage speed 1Multistage speed 1
Multistage speed 2Multistage speed 2
Multistage speed 3Multistage speed 3
Selection of multistage speedSelection of multistage speed
Note: ON indicates connection to COM terminal and OFF indicates break from COM terminal.Note: ON indicates connection to COM terminal and OFF indicates break from COM terminal.
Fig. 6-4 Diagram of Multistage Speed SelectionFig. 6-4 Diagram of Multistage Speed Selection
4
5 Remain
6
7
8
Acceleration/Deceleration time terminal:
This is applied to external terminal to select the acceleration/deceleration time.
FRD JOG control
REV JOG control
The above two control methods refer to FRD/REV JOG running control under the mode
of external terminal control.
Free stop control:
This refers to free stop control under the mode of external terminal control.
4 Acceleration/Deceleration time terminal:
This is applied to external terminal to select the acceleration/deceleration time.
5 Remain
6 FRD JOG control
7 REV JOG control
The above two control methods refer to FRD/REV JOG running control under the mode
of external terminal control.
8 Free stop control:
This refers to free stop control under the mode of external terminal control.
F100 F102 are used to set the fifth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F100 F102 are used to set the fifth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F103 F105 are used to set the sixth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F103 F105 are used to set the sixth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F106 F108 are used to set the sixth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.F106 F108 are used to set the sixth stage speed running time, direction, acceleration and deceleration time for programmable/multistage speed running.
F111 Setting Range:0 20 Factory Default Value: 0F111 Setting Range:0 20 Factory Default Value: 0
F112 Setting Range:0 20 Factory Default Value: 0F112 Setting Range:0 20 Factory Default Value: 0
F113 Setting Range:0 20 Factory Default Value: 0F113 Setting Range:0 20 Factory Default Value: 0
F114 Setting Range:0 20 Factory Default Value: 0F114 Setting Range:0 20 Factory Default Value: 0
F115 Setting Range:0 20 Factory Default Value: 0F115 Setting Range:0 20 Factory Default Value: 0
F116 Setting Range:0 20 Factory Default Value: 0F116 Setting Range:0 20 Factory Default Value: 0
F103 Setting Range:0.0 6000.0S Factory Default Value: 20.0SF103 Setting Range:0.0 6000.0S Factory Default Value: 20.0S
F104 Setting Range:0 1 Factory Default Value: 0F104 Setting Range:0 1 Factory Default Value: 0
F105 Setting Range:0.0 6000.0S Factory Default Value: 20.0SF105 Setting Range:0.0 6000.0S Factory Default Value: 20.0S
F106 Setting Range:0.0 6000.0S Factory Default Value: 20.0SF106 Setting Range:0.0 6000.0S Factory Default Value: 20.0S
F107 Setting Range:0 1 Factory Default Value: 0F107 Setting Range:0 1 Factory Default Value: 0
F108 Setting Range:0.0 6000.0S Factory Default Value: 20.0SF108 Setting Range:0.0 6000.0S Factory Default Value: 20.0S
The external input terminals X1 X6 are multi-function input terminals. The function of X1 X6
can be selected by setting the value of F111 F116. See detailed info on set value and function
instruction below:
The external input terminals X1 X6 are multi-function input terminals. The function of X1 X6
can be selected by setting the value of F111 F116. See detailed info on set value and function
instruction below:
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
st7 -stage speed running time
s t7 -stage speed running directionst7 -stage speed
acceleration/deceleration time
st6 -stage speed running time
s t6 -stage speed running direction
st6 -stage speed acceleration/deceleration time
Selection of multi-function input terminal X1
Selection of multi-function input terminal X2
Selection of multi-function input terminal X3
Selection of multi-function input terminal X4
Selection of multi-function input terminal X5
Selection of multi-function input terminal X6
The zero stage of multistage speed
The first stage of multistage speed
The second stage of multistage speed
The third stage of multistage speed
The fourth stage of multistage speed
The fifth stage of multistage speed
The sixth stage of multistage speed
The seventh stage of multistage speed
The running frequency at this stage is set by F080.
The running frequency at this stage is set by F081.
The running frequency at this stage is set by F082.
The running frequency at this stage is set by F083.
The running frequency at this stage is set by F084.
The running frequency at this stage is set by F085.
The running frequency at this stage is set by F086.
The running frequency at this stage is set by F087.
F117 Setting Range:0 10 Factory Default Value: 0F117 Setting Range:0 10 Factory Default Value: 0
F118 Setting Range:0 10 Factory Default Value: 0F118 Setting Range:0 10 Factory Default Value: 0
0 Inverter in operation signal
1:
3
When DC bus voltage is lower than the set level of under voltage, LED displays P.oFF and the
terminal Y outputs indication signal.
4
5
6
7:Inverter null revolution in service instruction
8
9
10 :
This set of parameters defines the contents of the open collector output terminals Y1 and Y2.
This indicates the outlet indication signal of the inverter in running state.
Frequency arrival (FAR) signal
Refer to the function declaration
2:Frequency level detection (FDT) signal:
Refer to the function declaration of F058.
Inverter under-voltage lockout:
External down:
When failure signal of external equipment is received through input terminal, the inverter will perform
trip alarm and the terminal Y outlets indication signal. Under the mode of non-key operation control,
press the STOP key and the terminal Y outputs indication signal.
Upper limit of output frequency arrival
This refers to the indication signal outlet by the inverter when the running frequency reaches the upper
limit of frequency.
Lower limit of output frequency arrival:
This refers to the indication signal outlet by the inverter when the running frequency reaches the lower
limit of frequency.
This indicates the indication signal outlet by the inverter is still in the state of operation though the
output frequency of the inverter is 0.
Easy PLC multistage running ends
When a PLC multi-speed operating cycle is finished, a valid low power level pulse signal will be output
at this port.
Inverter overload alarm signal
When the inverter's output current exceeds overload alarm level, an effective low power signal will be
output after waiting for a preset alarm delay period.
Count to output
The inverter will output this signal when count value reaches the setting value if counting function is
enabled.
This set of parameters defines the contents of the open collector output terminals Y1 and Y2.
0 Inverter in operation signal
This indicates the outlet indication signal of the inverter in running state.
1:Frequency arrival (FAR) signal
Refer to the function declaration
2:Frequency level detection (FDT) signal:
Refer to the function declaration of F058.
3 Inverter under-voltage lockout:
When DC bus voltage is lower than the set level of under voltage, LED displays P.oFF and the
terminal Y outputs indication signal.
4 External down:
When failure signal of external equipment is received through input terminal, the inverter will perform
trip alarm and the terminal Y outlets indication signal. Under the mode of non-key operation control,
press the STOP key and the terminal Y outputs indication signal.
5 Upper limit of output frequency arrival
This refers to the indication signal outlet by the inverter when the running frequency reaches the upper
limit of frequency.
6 Lower limit of output frequency arrival:
This refers to the indication signal outlet by the inverter when the running frequency reaches the lower
limit of frequency.
7:Inverter null revolution in service instruction
This indicates the indication signal outlet by the inverter is still in the state of operation though the
output frequency of the inverter is 0.
8 Easy PLC multistage running ends
When a PLC multi-speed operating cycle is finished, a valid low power level pulse signal will be output
at this port.
9 Inverter overload alarm signal
When the inverter's output current exceeds overload alarm level, an effective low power signal will be
output after waiting for a preset alarm delay period.
10 Count to output:
The inverter will output this signal when count value reaches the setting value if counting function is
enabled.
9 :
10 :
11
12
13
.
14
15
16 Remain
17
18 Remain
19 Once this function is set, connect this terminal to COM terminal and the counter value will be
0 .
20
Frequency UP Command
Frequency DOWN Command
The commands in 9 and 10 are used to realize control over frequency up or down, and proceed
remote control over operator panel.
External Failure Input:
This terminal paves the way for the inverter to keep an eye on external equipment failure by
inputting failure signals of external equipment.
Easy PLC Pause:
Easy PLC pause is applied to give pause control over PLC process which is in operation. The
equipment runs at 0 frequency if this terminal is valid and PLC running does not count the time.
Three-wire running control
Refer to the parameter F040
DC braking command:
DC braking command is used to apply DC braking on the motor in the course of stop, to realize
emergency shut-down and accurate positioning of the motor. See the parameter F030~F032 for
details.
External reset input:
When failure alarm occurs, this terminal is used to perform failure reset of the inverter. This
function is in accord with STOP key on the operator panel.
This is used to give a control over decelerating stop under the mode of external terminal
control.
Counter pulse signal input
This is used to receive the external pulse signal which is served as the count value (This function
can be set only by the multifunction terminal X6).
9 Frequency UP Command:
10 Frequency DOWN Command:
The commands in 9 and 10 are used to realize control over frequency up or down, and proceed
remote control over operator panel.
11 External Failure Input:
This terminal paves the way for the inverter to keep an eye on external equipment failure by
inputting failure signals of external equipment.
12 Easy PLC Pause:
Easy PLC pause is applied to give pause control over PLC process which is in operation. The
equipment runs at 0 frequency if this terminal is valid and PLC running does not count the time.
13 Three-wire running control
Refer to the parameter F040.
14 DC braking command:
DC braking command is used to apply DC braking on the motor in the course of stop, to realize
emergency shut-down and accurate positioning of the motor. See the parameter F030~F032 for
details.
15 External reset input:
When failure alarm occurs, this terminal is used to perform failure reset of the inverter. This
function is in accord with STOP key on the operator panel.
16 Remain
17 This is used to give a control over decelerating stop under the mode of external terminal
control.
18 Remain
19 Once this function is set, connect this terminal to COM terminal and the counter value will be
0 .
20 Counter pulse signal input
This is used to receive the external pulse signal which is served as the count value (This function
can be set only by the multifunction terminal X6).
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Function selection of collector output terminal Y1
Function selection of collector output terminal Y2
F125 Remain F125 Remain
F126 Setting Range:50.00 400.0Hz Factory Default Value:50.00HzF126 Setting Range:50.00 400.0Hz Factory Default Value:50.00Hz
F127 Setting Range:1 500V Factory Default Value: F127 Setting Range:1 500V Factory Default Value:
F128 Setting Range:0.1 999.0A Factory Default Value: F128 Setting Range:0.1 999.0A Factory Default Value:
F129 Setting Range:1 9999r/mm Factory Default Value: 1450F129 Setting Range:1 9999r/mm Factory Default Value: 1450
F126~F129 are used to set parameters for the controlled motor. Do set them properly
according to the data of specifications label on the motor.
F126~F129 are used to set parameters for the controlled motor. Do set them properly
according to the data of specifications label on the motor.
0
1
PID regulation not performed.
PID regulation performed.
PID regulation function is described below: The built-in PID controller in the inverter detects
physical quantity (feedback quantity) through the sensor of the object under control and compares
this quantity to the target value of the system. If deviation exists between them, then PID regulation
is used to remove deviation. It is a usual process control method used to keep the feedback quantity in
accord with the target value. This system structure is as shown in Fig. 6-27.
0 PID regulation not performed.
1 PID regulation performed.
PID regulation function is described below: The built-in PID controller in the inverter detects
physical quantity (feedback quantity) through the sensor of the object under control and compares
this quantity to the target value of the system. If deviation exists between them, then PID regulation
is used to remove deviation. It is a usual process control method used to keep the feedback quantity in
accord with the target value. This system structure is as shown in Fig. 6-27.
F130 Setting Range:0 1 Factory Default Value: 0PID action selection F130 PID action selection Setting Range:0 1 Factory Default Value: 0
PP
II
DD
Feedback quantity regulationFeedback quantity regulation
elementelement Object under controlObject under control
++
++
++
++
unctional Diagramunctional Diagram
F121 Setting Range:0 2 Factory Default Value: 0F121 Setting Range:0 2 Factory Default Value: 0
0
1
2
When selecting counting function enabled, then count pulse must be input by the multifunction
terminal X6, and X6 must select pulse input function (refer to F111~F116 Function Selections for
details), or this function will be invalid.
Counting function disabled.
Counting function enabled, up count mode.
Counting function enabled, down count mode.
When selecting counting function enabled, then count pulse must be input by the multifunction
terminal X6, and X6 must select pulse input function (refer to F111~F116 Function Selections for
details), or this function will be invalid.
0 Counting function disabled.
1 Counting function enabled, up count mode.
2 Counting function enabled, down count mode.
F122 Setting Range:0 9999 Factory Default Value: 1Count valueF122Count value Setting Range:0 9999 Factory Default Value: 1
This function is used to set pre-value for the counter. If up count mode is selected, the counter
will stop counting and perform counting to processing action when count value is equivalent to
preset value. If down count mode is selected, the counter will stop counting and performcounting
to processing action when count value is set to 1.
This function is used to set pre-value for the counter. If up count mode is selected, the counter
will stop counting and perform counting to processing action when count value is equivalent to
preset value. If down count mode is selected, the counter will stop counting and perform counting
to processing action when count value is set to 1.
F123 Setting Range:0 9999 Factory Default Value: 1Counting coefficientF123Counting coefficient Setting Range:0 9999 Factory Default Value: 1
This function is used to set unit value for each count pulse, and proceed counting on
relative items.
This function is used to set unit value for each count pulse, and proceed counting on
relative items.
F124 Setting Range:0 3 Factory Default Value: 0counting to processing selectionF124counting to processing selection Setting Range:0 3 Factory Default Value: 0
counting to action selection of the counter.
Stop counting
Recounting
counting to action selection of the counter.
Stop counting
Recounting
Counter Zero-clearance Operation:
Choose one of the external multifunction terminals X1~X6, set this
terminal with counter zero-clearance function and then connect this
terminal to COM terminal.
Counter Zero-clearance Operation:
Choose one of the external multifunction terminals X1~X6, set this
terminal with counter zero-clearance function and then connect this
terminal to COM terminal.
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Selection of counting modes
Motor's rated frequency
Motor's rated voltage
Motor's rated current
Motor's rated rotation speed Motor's rated rotation speed
Determined in accordance with specifications.Determined in accordance with specifications.
F135 Setting Range:0 1 Factory Default Value: 0F135 Setting Range:0 1 Factory Default Value: 0
0V 5V0V 5V
0V 0V 10V 10V
0mA 20mA0mA 20mA
100100
00
0
1
Positive
This indicates the maximum feedback
quantity corresponding to the maximum input
signal.
Negative
This indicates the maximum feedback
quantity corresponding to the minimum input
signal. Refer to Fig. 6-28 for details.
0 Positive
This indicates the maximum feedback
quantity corresponding to the maximum input
signal.
1 Negative
This indicates the maximum feedback
quantity corresponding to the minimum input
signal. Refer to Fig. 6-28 for details.
Fig. 6-28 Diagram of Feedback Polarity SelectionFig. 6-28 Diagram of Feedback Polarity Selection
F136 Setting Range:0.01 10.00 Factory Default Value:0.50F136 Setting Range:0.01 10.00 Factory Default Value:0.50
F137 Setting Range:0.0 100.0S Factory Default Value:10.0SIntegral time constant TiF137 Integral time constant Ti Setting Range:0.0 100.0S Factory Default Value:10.0S
F138 Setting Range:0.0 10.0S Factory Default Value:0.0S Differential time constant DiF138 Differential time constant Di Setting Range:0.0 10.0S Factory Default Value:0.0S
Proportional gain (P) decides response degree of output frequency to deviation. The greater the
P value is, the quicker response is, but excessive value of P may result in oscillation and too low
value of P may lead to response lagging.
Proportional gain (P) decides response degree of output frequency to deviation. The greater the
P value is, the quicker response is, but excessive value of P may result in oscillation and too low
value of P may lead to response lagging.
Integral time constant decides the proportional relation between output frequency change speed
and deviation. The function of integral is to integrate the output value in accordance with deviation
to compensate deviation between feedback value and set value. Too long integral time may result in
slow response to external disturbance. The shorter the constant time is, the quicker the response
speed is, but too short integral time may result in oscillation
Integral time constant decides the proportional relation between output frequency change speed
and deviation. The function of integral is to integrate the output value in accordance with deviation
to compensate deviation between feedback value and set value. Too long integral time may result in
slow response to external disturbance. The shorter the constant time is, the quicker the response
speed is, but too short integral time may result in oscillation
The function of differential is to proportionate output frequency to deviation, and respond
timely to abruptly changing deviation. The longer the differential time is, the faster decay of
system oscillation arising from proportional action is, but too long differential time may result in
oscillation. Vise versa, the shorter the differential time is, the less decay of oscillator is.
The function of differential is to proportionate output frequency to deviation, and respond
timely to abruptly changing deviation. The longer the differential time is, the faster decay of
system oscillation arising from proportional action is, but too long differential time may result in
oscillation. Vise versa, the shorter the differential time is, the less decay of oscillator is.
0
1
2
3
Set by the / key on the operator panel.
Set closed-loop feed quantity according to the target value of F132.
Set by external voltage signal V 0~10V .
Set the target value according to external voltage signal V 0~10V .
Set by external current signal I 0~20mA .
Set the target value according to external current signal I 0~20mA .
Set by 485 COM.
Set the target value according to 485 COM.
0 Set by the / key on the operator panel.
Set closed-loop feed quantity according to the target value of F132.
1 Set by external voltage signal V 0~10V .
Set the target value according to external voltage signal V 0~10V .
2 Set by external current signal I 0~20mA .
Set the target value according to external current signal I 0~20mA .
3 Set by 485 COM.
Set the target value according to 485 COM.
F131 Setting Range:0 3 Factory Default Value: 0F131 Setting Range:0 3 Factory Default Value: 0
F132 Setting Range:0.00 10.00V Factory Default Value:0.0VF132 Setting Range:0.00 10.00V Factory Default Value:0.0V
F133 Setting Range:0 1 Factory Default Value: 0F133 Setting Range:0 1 Factory Default Value: 0
When PID target value setting mode selects setting by / key on the operator panel
F131=0 , then this parameter is used to set the target value of PID control with V as its unit.
When PID target value setting mode selects setting by / key on the operator panel
F131=0 , then this parameter is used to set the target value of PID control with V as its unit.
0
1
External voltage signal V 0~10V :
Select external voltage signal V(0~10V) as closed-loop feedback quantity.
External current signal I 0~20mA :
Select external current signal I(0~20mA) as closed-loop feedback quantity.
0 External voltage signal V 0~10V :
Select external voltage signal V(0~10V) as closed-loop feedback quantity.
1 External current signal I 0~20mA :
Select external current signal I(0~20mA) as closed-loop feedback quantity.
F134 Setting Range:0.01 10.00 Factory Default Value:1.00F134 Setting Range:0.01 10.00 Factory Default Value:1.00
When feedback quantity is not in accord with set target value, then this parameter can be used to
regulate feedback quantity signal till PID regulation meets the requirement.
When feedback quantity is not in accord with set target value, then this parameter can be used to
regulate feedback quantity signal till PID regulation meets the requirement.
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Selection of PID target value setting mode
PID target value setting
Selection of feedback modes
PID feedback quantity gain
PID feedback polarity selection
Proportional gain (P)
F142 indicates the pressure limit of water supply system when it enters into working state from
sleeping state.
When network pressure is lower than the setting value, which means water supply pressure
decreases or water consumption increases, the frequency changing water supply system will
automatically shift to the working state from sleeping state.
If water supply system conforms to the conditions for both sleep and wake-up, then the wait time
for sleep or wake-up will be set by F143.
F142 indicates the pressure limit of water supply system when it enters into working state from
sleeping state.
When network pressure is lower than the setting value, which means water supply pressure
decreases or water consumption increases, the frequency changing water supply system will
automatically shift to the working state from sleeping state.
If water supply system conforms to the conditions for both sleep and wake-up, then the wait time
for sleep or wake-up will be set by F143.
F145 Setting Range:0 1 Factory Default Value: 0F145 Setting Range:0 1 Factory Default Value: 0
0
1
Free stop
When the motor or inverter overloads, the inverter will stop its output and the motor will
shutdown freely.
Current-limiting running
When the motor or inverter overloads, the inverter will decrease output frequency to reduce load
current, output alerting signal at the same time and the alarm indicator on the operator panel will
turn on.
0 Free stop
When the motor or inverter overloads, the inverter will stop its output and the motor will
shutdown freely.
1 Current-limiting running
When the motor or inverter overloads, the inverter will decrease output frequency to reduce load
current, output alerting signal at the same time and the alarm indicator on the operator panel will
turn on.
F146 Setting Range:0 1 Factory Default Value: 1F146 Setting Range:0 1 Factory Default Value: 1
1 Forbidden
1 Allowable
Input open-phase protection disabled.
Input open-phase protection enabled.
1 Forbidden
Input open-phase protection disabled.
1 Allowable
Input open-phase protection enabled.
The function of input open-phase protection shall be selected
cautiously after the failure cause is confirmed. Otherwise, there is the
possibility of damage to the inverter, loss of property, injury or even
death to personnel.
The function of input open-phase protection shall be selected
cautiously after the failure cause is confirmed. Otherwise, there is the
possibility of damage to the inverter, loss of property, injury or even
death to personnel.
Deviation limit refers to the maximum value of deviation between feedback quantity and set
quantity within allowable range of the system. When the difference (modulus) between feedback
quantity and set quantity is lower than this set parameter value, PID control enabled. As shown in Fig.
6-29, proper setting of this parameter is of advantage to improve the stability of the output of system
which needs to avoid frequent regulation though it has no high requirement on control precision.
Deviation limit refers to the maximum value of deviation between feedback quantity and set
quantity within allowable range of the system. When the difference (modulus) between feedback
quantity and set quantity is lower than this set parameter value, PID control enabled. As shown in Fig.
6-29, proper setting of this parameter is of advantage to improve the stability of the output of system
which needs to avoid frequent regulation though it has no high requirement on control precision.
F139 Setting Range:0.01 1.00S Factory Default Value:0.10SSampling periodF139 Sampling period Setting Range:0.01 1.00S Factory Default Value:0.10S
Sampling period refers to the cycle in which the system conducts sampling over feedback
quantity. PID regulator makes a calculation in each period of sampling and gets the output value of
PID regulation. The longer the sampling period is, the slower the response is.
Sampling period refers to the cycle in which the system conducts sampling over feedback
quantity. PID regulator makes a calculation in each period of sampling and gets the output value of
PID regulation. The longer the sampling period is, the slower the response is.
PID feedbackPID feedback
PIDPID
Deviation limitDeviation limit
PID PID PIDPID
Fig. 6-29 Deviation Limit Function DiagramFig. 6-29 Deviation Limit Function Diagram
F140 Setting Range:0.0 20.0% Factory Default Value:0.0%Deviation limit F140 Deviation limit Setting Range:0.0 20.0% Factory Default Value:0.0%
F143 Setting Range:0.0 6000.0S Factory Default Value:0.0SF143 Setting Range:0.0 6000.0S Factory Default Value:0.0S
F141 indicates the pressure limit of water supply system in the state of sleep.
When network pressure is higher than this setting value and the frequency changing water
supply system is adjusted to run at the minimum frequency, which means the actual water
consumption minimizes or the water supply pressure is normal, the frequency changing water
supply system will enter automatically into the state of sleep, stop and wait for wake-up.
F141 indicates the pressure limit of water supply system in the state of sleep.
When network pressure is higher than this setting value and the frequency changing water
supply system is adjusted to run at the minimum frequency, which means the actual water
consumption minimizes or the water supply pressure is normal, the frequency changing water
supply system will enter automatically into the state of sleep, stop and wait for wake-up.
F141 Setting Range:F142 100.0% Factory Default Value:90.0%Sleep thresholdF141 Sleep threshold Setting Range:F142 100.0% Factory Default Value:90.0%
F142 Setting Range:0.0% F141 Factory Default Value:0.0%Wake-up thresholdF142 Wake-up threshold Setting Range:0.0% F141 Factory Default Value:0.0%
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Check-out time for sleep/wake-up threshold
Selection of overload and overheat protection
Selection of input open-phase protection
The function of failure self-resetting indicates the failure arising from load fluctuation or other
causes can reset automatically in accordance with set times and interval. During the process of self-
resetting, the inverter will restore operation by way of rotation speed tracing and restarting. When
the self-resetting times is set to 0 , this indicates self reset is disabled and failure protection
should be done immediately. This function is invalid for failure protection caused by overload or
over heat.
The function of failure self-resetting indicates the failure arising from load fluctuation or other
causes can reset automatically in accordance with set times and interval. During the process of self-
resetting, the inverter will restore operation by way of rotation speed tracing and restarting. When
the self-resetting times is set to 0 , this indicates self reset is disabled and failure protection
should be done immediately. This function is invalid for failure protection caused by overload or
over heat.
Output currentOutput current
Output FrequencyOutput Frequency
F150 Setting Range:40 200% Factory Default Value:150%F150 Setting Range:40 200% Factory Default Value:150%
F151 Setting Range:40 200% Factory Default Value:150%F151 Setting Range:40 200% Factory Default Value:150%
This parameter defines current threshold of the inverter in the process of accelerated or
constant speed running, that is, stall power level, whose setting value is in respect tothe
percentage of rated current of the inverter. During accelerated or constant speed running, once
the inverter's output current exceeds over-current stall power level, the inverter will regulate its
acceleration time immediately and maintain the current at this level automatically to protect the
motor, as shown in Fig. 6-31.
This parameter defines current threshold of the inverter in the process of accelerated or
constant speed running, that is, stall power level, whose setting value is in respect to the
percentage of rated current of the inverter. During accelerated or constant speed running, once
the inverter's output current exceeds over-current stall power level, the inverter will regulate its
acceleration time immediately and maintain the current at this level automatically to protect the
motor, as shown in Fig. 6-31.
Fig. 6-31 Diagram of Automatic Current-limiting OperationFig. 6-31 Diagram of Automatic Current-limiting Operation
F152 Setting Range:0 3 Factory Default Value: 0Failure self-resetting timesF152 Failure self-resetting times Setting Range:0 3 Factory Default Value: 0
F153 Setting Range:1 30S Factory Default Value: 5SFailure self-resetting intervalF153 Failure self-resetting interval Setting Range:1 30S Factory Default Value: 5S
DO take into consideration of the starting characteristic of
mechanical equipment cautiously before using this function. DO NOT
apply this function in case starting with load failed.
DO take into consideration of the starting characteristic of
mechanical equipment cautiously before using this function. DO NOT
apply this function in case starting with load failed.
F147 Setting Range:0 1 Factory Default Value: 1F147 Setting Range:0 1 Factory Default Value: 1
Motor overload protection CoefficientMotor overload protection Coefficient
80%80% 100%100%
22
120120%% 150%150%
F148 Setting Range:30 110% Factory Default Value:100%F148 Setting Range:30 110% Factory Default Value:100%
F149 Setting Range:0 1 Factory Default Value: 1F149 Setting Range:0 1 Factory Default Value: 1
During decelerated service of the inverter, the motor's rotation speed may be higher than the
inverter's output frequency due to the influence of load inertia. At this time, the motor feedbacks
energy to the inverter, which results in rise of the inverter's DC bus voltage. During deceleration,
when DC bus voltage exceeds certain power level, the over-voltage stall prevention function will be
enabled, which can automatically adjust the inverter's deceleration rate to avoid over-voltage
tripping.
During decelerated service of the inverter, the motor's rotation speed may be higher than the
inverter's output frequency due to the influence of load inertia. At this time, the motor feedbacks
energy to the inverter, which results in rise of the inverter's DC bus voltage. During deceleration,
when DC bus voltage exceeds certain power level, the over-voltage stall prevention function will be
enabled, which can automatically adjust the inverter's deceleration rate to avoid over-voltage
tripping.
To perform effective overload protection of load motors with different specifications, it is
necessary to set proper overload protection coefficient for each type of motor and restrict the
maximum current value within the allowable output range of the inverter, as shown in Fig. 6-30.
The overload protection coefficient value of a motor is the percentage of rated current value of the
load motor to rated output current value of the inverter.
To perform effective overload protection of load motors with different specifications, it is
necessary to set proper overload protection coefficient for each type of motor and restrict the
maximum current value within the allowable output range of the inverter, as shown in Fig. 6-30.
The overload protection coefficient value of a motor is the percentage of rated current value of the
load motor to rated output current value of the inverter.
Fig. 6-30 Motor Overload Protection CurveFig. 6-30 Motor Overload Protection Curve
1 Forbidden
1 Allowable
The function of auto current-limiting is always valid in the state of acceleration or deceleration.
If this function parameter is set to “1”, then auto current-limiting function also acts under the
condition of constant speed, and the motor will be protected through input current regulation of the
inverter.
1 Forbidden
1 Allowable
The function of auto current-limiting is always valid in the state of acceleration or deceleration.
If this function parameter is set to “1”, then auto current-limiting function also acts under the
condition of constant speed, and the motor will be protected through input current regulation of the
inverter.
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Selection of over-voltage stall prevention function
Motor thermal relay protection coefficient
Selection of automatic current-limiting function
Over-current stall prevention level during acceleration
Over-current stall prevention level during constant speed
F155 Setting Range:0 30 Factory Default Value: 1COM local addressF155 COM local address Setting Range:0 30 Factory Default Value: 1
This parameter is used to identify the local inverter's address which is unique when an inverter
communicates with other inverters or upper machines through COM port.
If this parameter is set to 0 , the local inverter under linking control will act as the main
station, which decides the operation of other inverters connected to it.
If this parameter is not set to 0 , the local inverter will act as a secondary receiving
commands and data from an upper machine or another inverter acting as the role of main station.
The inverter receives only commands and data from the upper machine or the main station in
accord with marked address.
This parameter is used to identify the local inverter's address which is unique when an inverter
communicates with other inverters or upper machines through COM port.
If this parameter is set to 0 , the local inverter under linking control will act as the main
station, which decides the operation of other inverters connected to it.
If this parameter is not set to 0 , the local inverter will act as a secondary receiving
commands and data from an upper machine or another inverter acting as the role of main station.
The inverter receives only commands and data from the upper machine or the main station in
accord with marked address.
F156 Setting Range:0 2 Factory Default Value: 0COM data formatF156 COM data format Setting Range:0 2 Factory Default Value: 0
0
1
2
The parameter defines data format adopted in COM protocol, and normal communication goes on
only if the format is in accord with the protocol.
No parity
Even parity
Odd parity
All the data formats are set to 1-bit starting location, 8-bit data location and 1-bit stop location.
The parameter defines data format adopted in COM protocol, and normal communication goes on
only if the format is in accord with the protocol.
0 No parity
1 Even parity
2 Odd parity
All the data formats are set to 1-bit starting location, 8-bit data location and 1-bit stop location.
F157 Setting Range:0 5 Factory Default Value: 3COM baud rate selectionF157COM baud rate selection Setting Range:0 5 Factory Default Value: 3
0 1200BPS 1 2400BPS 2 4800BPS 3 9600BPS
4 19200BPS 4 38400BPS
This parameter is used to specify the baud rate of RS485/232 communication, and the same
baud rate shall be set to all parties involved in communication.
This parameter is used to specify the baud rate of RS485/232 communication, and the same
baud rate shall be set to all parties involved in communication.
0 1200BPS 1 2400BPS 2 4800BPS 3 9600BPS
4 19200BPS 4 38400BPS
F158 Setting Range:0.01 10.00 Factory Default Value:1.00COM linking ratio F158COM linking ratio Setting Range:0.01 10.00 Factory Default Value:1.00
If local inverter is set to be controlled by master inverter and the setting frequency of local
machine is given by the master inverter, then this parameter is used to set weight coefficient of
frequency instruction received by the local inverter which acts as a secondary through RS485/232
port. The actual setting frequency of local inverter is equivalent to the product of local parameter
value and the frequency setting instruction value received through RS485/232 port.
If local inverter is set to be controlled by master inverter and the setting frequency of local
machine is given by the master inverter, then this parameter is used to set weight coefficient of
frequency instruction received by the local inverter which acts as a secondary through RS485/232
port. The actual setting frequency of local inverter is equivalent to the product of local parameter
value and the frequency setting instruction value received through RS485/232 port.
Running time S stands for second(s) and H stands for hour(s). The running time can be
reviewed only and cannot be modified.
Running time S stands for second(s) and H stands for hour(s). The running time can be
reviewed only and cannot be modified.
F163 Setting Range:0 1 Factory Default Value: 1Frequency power failure memoryF163 Frequency power failure memory Setting Range:0 1 Factory Default Value: 1
0 1
No memory Keep memory
This function indicates whether the running frequency regulated randomly keeps and stores
memory or not after power failure.
0 No memory 1 Keep memory
This function indicates whether the running frequency regulated randomly keeps and stores
memory or not after power failure.
0
1
This function can realize control over built-in cooling fan of the inverter.
The fan runs continuously (independent of whether the inverter is power-on or power-off).
Fan-controlled running. (When the inverter starts, the cooling fan works. During shutdown,
the fan keeps a watch on the state of inverter and decides to start or stop the fan in accordance with
temperature.)
This function can realize control over built-in cooling fan of the inverter.
0 The fan runs continuously (independent of whether the inverter is power-on or power-off).
1 Fan-controlled running. (When the inverter starts, the cooling fan works. During shutdown,
the fan keeps a watch on the state of inverter and decides to start or stop the fan in accordance with
temperature.)
F164 Setting Range:0 1 Factory Default Value: 1Ventilator fan controlF164 Ventilator fan control Setting Range:0 1 Factory Default Value: 1
0 1
This function is used to control over the inverter's carrier frequency (below 10.00Hz) whether
it can change automatically or not with variation of output frequency ranging from 1.0KHz to the
set carrier frequency
Invalid Valid
This function is used to control over the inverter's carrier frequency (below 10.00Hz) whether
it can change automatically or not with variation of output frequency ranging from 1.0KHz to the
set carrier frequency
0 Invalid 1 Valid
F165 Setting Range:0 1 Factory Default Value: 1PWM adaptive controlF165 PWM adaptive control Setting Range:0 1 Factory Default Value: 1
0
1
2
This is used to set modification authority for parameters. See the detail below:
This indicates all the parameters are permitted to be overwritten, but some can not be
overwritten when the equipment is in operation.
All the parameters are prohibited to be overwritten except numeric setting frequency and
this parameter.
All the parameters are prohibited to be overwritten except this parameter.
This is used to set modification authority for parameters. See the detail below:
0 This indicates all the parameters are permitted to be overwritten, but some can not be
overwritten when the equipment is in operation.
1 All the parameters are prohibited to be overwritten except numeric setting frequency and
this parameter.
2 All the parameters are prohibited to be overwritten except this parameter.
F159 Setting Range:0 2 Factory Default Value: 0Parameter write-protectF159 Parameter write-protect Setting Range:0 2 Factory Default Value: 0
Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters Chapter 6 Description of Function ParametersChapter 6 Description of Function Parameters
Chapter 7 Common Problems, Anomalies and TroubleshootingChapter 7 Common Problems, Anomalies and Troubleshooting
7.1 Diagnostic Trouble Codes and Troubleshooting7.1 Diagnostic Trouble Codes and Troubleshooting
Table 7-1 Common Error Codes and SolutionsTable 7-1 Common Error Codes and Solutions
Error CodesError Codes Error NameError Name Probable Cause(s)Probable Cause(s) Solution(s)Solution(s)
Over current during acceleration
Over current during acceleration
Over current during deceleration
Over current during deceleration
Over current while at constant speed
Over current while at constant speed
Over voltage during acceleration
Over voltage during acceleration
Over voltage during deceleration
Over voltage during deceleration
Over voltage while at constant speed
Over voltage while at constant speed
Excessively short acceleration time
Excessively heavy load inertia
Over torque lifting or improper V/F curve
Power grid voltage below level
Lower inverter powerRestart the rotating motor
when instantaneous power failure occurred
Excessively short acceleration time
Excessively heavy load inertia
Over torque lifting or improper V/F curve
Power grid voltage below level
Lower inverter powerRestart the rotating motor
when instantaneous power failure occurred
Excessively short deceleration time
Excessively heavy load inertia
Lower inverter power
Excessively short deceleration time
Excessively heavy load inertia
Lower inverter power
;;
;
Abnormal input power supply
Load fluctuationLower inverter power
Abnormal input power supply;
Load fluctuation;Lower inverter power;
Abnormal input power supply
Restart the rotating motor when instantaneous power failure occurred
Abnormal input power supply
Restart the rotating motor when instantaneous power failure occurred
Excessively short deceleration time
Existence of load with energy feedback
Abnormal input power supply
Excessively short deceleration time
Existence of load with energy feedback
Abnormal input power supply
..
Abnormal input power supplyLoad with energy feedbackAbnormal voltage detecting
channel.
Abnormal input power supply.Load with energy feedback.Abnormal voltage detecting
channel.
Check input power supplyReduce load fluctuationReplace an inverter with higher
power level
Check input power supplyReduce load fluctuationReplace an inverter with higher
power level
Extend acceleration time
Reduce load inertia
Reduce torque lifting value
or regulate V/F curve
Check input power supply
Replace an inverter with
larger power
Set starting mode selection
F023 to rotation speed
tracing.
Extend acceleration time
Reduce load inertia
Reduce torque lifting value
or regulate V/F curve
Check input power supply
Replace an inverter with
larger power
Set starting mode selection
F023 to rotation speed
tracing.
Extend deceleration timeReduce load inertiaReplace an inverter with higher
power level
Extend deceleration timeReduce load inertiaReplace an inverter with higher
power level
Check input power supplySet starting mode selection F023 to
rotation speed tracing.
Check input power supplySet starting mode selection F023 to
rotation speed tracing.
Extend deceleration time adequately.
Select suitable brake assembly.
Check input power supply.
Extend deceleration time adequately.
Select suitable brake assembly.
Check input power supply.
Check input power supply.
Install or reselect brake assembly.
Seek service.
Check input power supply.
Install or reselect brake assembly.
Seek service.
Chapter 7 Common Problems, Anomalies and TroubleshootingChapter 7 Common Problems, Anomalies and Troubleshooting
Over voltage while at stopOver voltage while at stop
Under-voltage during runningUnder-voltage during running
Input end open-phaseInput end open-phase
Power module errorPower module error
Radiator overheat Radiator overheat
Inverter overloadInverter overload
.Abnormal input power
supplyAbnormal input power
supply.
.
..
Input power supply below level
Instantaneous power failure
Input power failureDC circuit loose contact.Loose contactor.
Input power supply below level.
Instantaneous power failure.
Input power failure.DC circuit loose contact.Loose contactor.
.
Phase fault or ground fault of three output phases of the inverter.
Instantaneous over current of the inverter
Excess ambient temperature.Air channel binding or fan
damagedDC accessory power supply
failureAbnormal control panel.
Phase fault or ground fault of three output phases of the inverter.
Instantaneous over current of the inverter.
Excess ambient temperature.Air channel binding or fan
damagedDC accessory power supply
failureAbnormal control panel.
.Excess ambient temperature.Fan damagedAir channel binding.
Excess ambient temperature.Fan damaged.Air channel binding.
Over torque lifting or improper V/F curve.
Excessively short acceleration time
OverloadPower grid voltage below
level.
Over torque lifting or improper V/F curve.
Excessively short acceleration time
OverloadPower grid voltage below
level.
Open phase of power input end R , S or T .
Open phase of power input end R , S or T .
Check input power supply.Check input power supply.
Check if power supply voltage is below level.
Reset the inverter and check input power supply.
Check if power grid capacity is below level. Verify if power supply voltage is normal. Is there any strong surge current, open phase or short circuit?
Check the main circuit or seek service.Check the contactor or seek service.
Check if power supply voltage is below level.
Reset the inverter and check input power supply.
Check if power grid capacity is below level. Verify if power supply voltage is normal. Is there any strong surge current, open phase or short circuit?
Check the main circuit or seek service.Check the contactor or seek service.
Check input voltage.Check installation wiring.Check input voltage.Check installation wiring.
Check wiring.Improve ventilation conditions and
reduce carrier frequency.Clear up air channel or replace the
fan.Seek service.Seek service.
Check wiring.Improve ventilation conditions and
reduce carrier frequency.Clear up air channel or replace the
fan.Seek service. Seek service.
Lower the ambient temperature.Replace the fan.Clear up air channel or improve
ventilation conditions.
Lower the ambient temperature.Replace the fan.Clear up air channel or improve
ventilation conditions.
Reduce torque lifting value or regulate V/F curve.
Extend acceleration time.Replace an inverter with higher
power level.Check power grid voltage.
Reduce torque lifting value or regulate V/F curve.
Extend acceleration time.Replace an inverter with higher
power level.Check power grid voltage.
Error CodesError Codes Error NameError Name Probable Cause(s)Probable Cause(s) Solution(s)Solution(s)
Chapter 7 Common Problems, Anomalies and TroubleshootingChapter 7 Common Problems, Anomalies and Troubleshooting
Chapter 7 Common Problems, Anomalies and TroubleshootingChapter 7 Common Problems, Anomalies and Troubleshooting
7.2 Anomalies and Solutions7.2 Anomalies and Solutions
Table 7-2 Anomalies and SolutionsTable 7-2 Anomalies and Solutions
AnomaliesAnomalies
No display when the power is ON
No display when the power is ON
Power tripPower trip
Motor doesn't runMotor doesn't run
Motor reversesMotor reverses
Motor acceleration/deceleration failed
Motor acceleration/deceleration failed
Motor's speed fluctuates while at constant speed
Motor's speed fluctuates while at constant speed
Power grid voltage below level or open phase.
DC accessory power supply failure.
Charging resistor damaged.
Power grid voltage below level or open phase.
DC accessory power supply failure.
Charging resistor damaged.
Short circuit in the inverter's input side
Exiguous air switching capacity.
Short circuit in the inverter's input side
Exiguous air switching capacity.
.Incorrect wiring
Error setting of operation mode.
Overload or motor stalled.
Incorrect wiring.
Error setting of operation mode.
Overload or motor stalled.
Error phase sequence of motor
wiring.
Error phase sequence of motor
wiring.
.
.
.
Improper setting of acceleration/deceleration time
Under setting of over-current stall points.
Over-voltage stall prevention enabled
Improper setting of carrier frequency or oscillation occurred
Overload.
Improper setting of acceleration/deceleration time.
Under setting of over-current stall points.
Over-voltage stall prevention enabled.
Improper setting of carrier frequency or oscillation occurred.
Overload.
.
.
Excessive fluctuation of loads
Under setting of motor's
overload protection coefficient
Loose contact of frequency
setting potentiometer.
Excessive fluctuation of loads.
Under setting of motor's
overload protection coefficient.
Loose contact of frequency
setting potentiometer.
Check power grid voltage.
Seek service.
Seek service.
Check power grid voltage.
Seek service.
Seek service.
Check wiring or seek service.
Expand air switching capacity.
Check wiring or seek service.
Expand air switching capacity.
Check wiring.
Reset the operation mode.
Reduce loads or regulate motor's status.
Check wiring.
Reset the operation mode.
Reduce loads or regulate motor's status.
Swap random two phases of the output
terminals U, V and W.
Swap random two phases of the output
terminals U, V and W.
Reset acceleration/deceleration time.Increase setting value for over-current
stall point.Extend deceleration time or reduce load
inertia.Reduce carrier frequency.Reduce load or replace an inverter with
higher power level.
Reset acceleration/deceleration time.Increase setting value for over-current
stall point.Extend deceleration time or reduce load
inertia.Reduce carrier frequency.Reduce load or replace an inverter with
higher power level.
Reduce load fluctuation.
Increase overload protection coefficient.
Replace the potentiometer or seek
service.
Reduce load fluctuation.
Increase overload protection coefficient.
Replace the potentiometer or seek
service.
Chapter 7 Common Problems, Anomalies and TroubleshootingChapter 7 Common Problems, Anomalies and Troubleshooting
Motor overloadMotor overload
External equipment failure
External equipment failure
Current detection error
Current detection error
Over torque lifting or improper V/F curve.
Power grid voltage below level.
Motor stalled or excessive load fluctuation.
Improper setting of the motor's overload protection coefficient.
Over torque lifting or improper V/F curve.
Power grid voltage below level.
Motor stalled or excessive load fluctuation.
Improper setting of the motor's overload protection coefficient.
Close of fault input terminal of external equipment.
Close of fault input terminal of external equipment.
Damaged hall elements or circuit failure.
DC accessory power supply failure.
Damaged hall elements or circuit failure.
DC accessory power supply failure.
Panel communication failure
Panel communication failure
RS485 COM errorRS485 COM error
Circuit failure of patch panel and control panel.
Loose connection of terminals.
Circuit failure of patch panel and control panel.
Loose connection of terminals.
.Improper setting of baud rateCommunication failure due to
interference at serial port.No communication signal of
the upper machine.
Improper setting of baud rate.Communication failure due to
interference at serial port.No communication signal of
the upper machine.
Reduce torque lifting value or
regulate V/F curve.
Check power grid voltage.
Check loads and motor's status.
Set proper overload protection
coefficient F148 of the motor.
Reduce torque lifting value or
regulate V/F curve.
Check power grid voltage.
Check loads and motor's status.
Set proper overload protection
coefficient F148 of the motor.
Disconnect fault input terminal of external equipment and clear failure.
Disconnect fault input terminal of external equipment and clear failure.
Seek service.
Seek service.
Seek service.
Seek service.
Seek service.
Check and re-connect.
Seek service.
Check and re-connect.
Adjust baud rate.Check the communication cable
and take anti-interference measures.Check if the upper machine runs
normally and the communication cable is disconnected.
Adjust baud rate.Check the communication cable
and take anti-interference measures.Check if the upper machine runs
normally and the communication cable is disconnected.
Error CodesError Codes Error NameError Name Probable Cause(s)Probable Cause(s) Solution(s)Solution(s)
Probable Cause(s)Probable Cause(s) Solution(s)Solution(s)
Table 8-1 Daily Check ListTable 8-1 Daily Check List
8.1 Inspection and Maintenance8.1 Inspection and Maintenance
The following influences may lead to latent failure of the inverter such as ambient temperature, humidity, dust, vibration, as well as device ageing, wear and other causes of the inverter itself during long-period operation on industrial occasions. So it is necessary to perform daily and periodic inspections and maintenance on the inverter.
The following influences may lead to latent failure of the inverter such as ambient temperature, humidity, dust, vibration, as well as device ageing, wear and other causes of the inverter itself during long-period operation on industrial occasions. So it is necessary to perform daily and periodic inspections and maintenance on the inverter.
8.1.1 Daily Inspection Items 8.1.1 Daily Inspection Items
Chapter 8 Inverter Inspection and MaintenanceChapter 8 Inverter Inspection and Maintenance
Inspection CycleInspection Cycle
DailyDaily
Ambient
temperature
Humidity, dust,
corrosive gas, oil
mist and etc.
Ambient
temperature
Humidity, dust,
corrosive gas, oil
mist and etc.
Vibration
Heat
Noise
Vibration
Heat
Noise
Vibration
Heat
Noise
Vibration
Heat
Noise
Output Voltage
Input voltage
Output current
Input voltage
Output Voltage
Output current
Inspection MethodInspection Method
Thermometer.
Scent.
Visual.
Thermometer.
Scent.
Visual.
ThermometerThermometer
Touch the
housing.
Aural.
Touch the
housing.
Aural.
Touch the
housing.
Aural.
Touch the
housing.
Aural.
CriteriaCriteria
Ambient temperature between -10 to 40 , no-condensing
Humidity between 20 to 90% no dew or special odor.
Ambient temperature between -10 to 40 , no-condensing
Humidity between 20 to 90% no dew or special odor.
Each electric
parameter is
within the rated
value.
Each electric
parameter is
within the rated
value.
Measuring InstrumentMeasuring Instrument
Thermometer
Hygrometer
Thermometer
Hygrometer
Moving-iron voltmeter
Rectifier voltmeter
Clip-on ammeter
Moving-iron voltmeter
Rectifier voltmeter
Clip-on ammeter
8.1.2 Periodic Inspection Items8.1.2 Periodic Inspection ItemsTable 8-2 Periodic Inspection ItemsTable 8-2 Periodic Inspection Items
Make sure that only qualified personnel will perform maintenance,
inspection and part replacement.
Wait at least 10 minutes after turning OFF the input power supply
before performing maintenance or an inspection. Otherwise, there is
the danger of electric shock.
Make sure to open the front panel only after the indicator on the
control keypad turns OFF and verify the charge indicator at the
right side of main loop terminal is OFF after the panel is opened.
Do use an insulated appliance while performing check and do not
operate the equipment with wet hand(s) to avoid unexpected
accidents.
Always keep the equipment clean so that dust and other foreign
matter does not enter the inverter.
Keep electronic equipment away from moisture and oil. Dust,
steel filings and other foreign matter can damage the inverter,
causing unexpected accidents, so do take special care.
Make sure that only qualified personnel will perform maintenance,
inspection and part replacement.
Wait at least 10 minutes after turning OFF the input power supply
before performing maintenance or an inspection. Otherwise, there is
the danger of electric shock.
Make sure to open the front panel only after the indicator on the
control keypad turns OFF and verify the charge indicator at the
right side of main loop terminal is OFF after the panel is opened.
Do use an insulated appliance while performing check and do not
operate the equipment with wet hand(s) to avoid unexpected
accidents.
Always keep the equipment clean so that dust and other foreign
matter does not enter the inverter.
Keep electronic equipment away from moisture and oil. Dust,
steel filings and other foreign matter can damage the inverter,
causing unexpected accidents, so do take special care.
Main circu
itM
ain circuit
ContactorContactor
Regular
Regular
Regular
Regular
Regular
Regular
Regular
Regular
WARNINGWARNING
Chapter 8 Inverter Inspection and MaintenanceChapter 8 Inverter Inspection and Maintenance
Chapter 8 Inverter Inspection and Maintenance
Item Inspected
Operating ambient
Inverter
Motor
Electric Parameter DailyDaily
DailyDaily
Stable vibrationNormal
temperatureNo abnormal
noise
Stable vibrationNormal
temperatureNo abnormal
noise
Stable vibrationNormal
temperatureNo abnormal
noise
Stable vibrationNormal
temperatureNo abnormal
noise
DailyDaily
CriteriaCriteriaInspection CycleInspection CycleItem Inspected Inspection
Method
OverallOverall
Main power moduleMain power module
Filter capacitanceFilter capacitance
Visual
Visual
Visual
Visual AuralAural
Is there any loose
connector or terminal?
Is there any device
burnt?
No loose connector
or loose terminal.
No burnt device.
Is it damaged or not? No sign of damage.
Is there any leakage?
Is there any inflation?
No leakage.
No inflation.
Is there any abnormal
sound of actuation?
Is the dust cleaned?
Normal sound
Clean
Do not remove or shake the device arbitrarily, nor pull out the
connector during inspection. Otherwise, this may result in inverter
failure or damage.
Do not leave any inspection tool (i.e., a screwdriver ) in the
machine after periodic check. Otherwise, there is the danger of
damage to the inverter.
Do not remove or shake the device arbitrarily, nor pull out the
connector during inspection. Otherwise, this may result in inverter
failure or damage.
Do not leave any inspection tool (i.e., a screwdriver ) in the
machine after periodic check. Otherwise, there is the danger of
damage to the inverter.
Main circu
itM
ain circuit
Co
ntro
l circuit
Co
ntro
l circuit
Key
bo
ardK
eyb
oard
Is there any big crack?
Is there any big crack?
Is the color abnormal?
Is the color abnormal?
VisualVisual
No crack.
Normal color.
No crack.
Normal color.
Normal and clear.Normal and clear.
WARNINGWARNING
Replacement of Wearing PartsReplacement of Wearing Parts
The wearing parts of inverter mainly include cooling fan and filter electrolytic
capacitor. Usually, a cooling fan's service life is 20,000~30,000 hours and an
electrolytic capacitor's service life is 40,000~50,000 hours. User can decide when to
replace these parts according to the corresponding operation time.
The wearing parts of inverter mainly include cooling fan and filter electrolytic
capacitor. Usually, a cooling fan's service life is 20,000~30,000 hours and an
electrolytic capacitor's service life is 40,000~50,000 hours. User can decide when to
replace these parts according to the corresponding operation time.
Cooling FanCooling Fan It is advisory to replace the fan when abnormal noise or even vibration occurred to the
fan due to bearing wear and fan blade aging. The standard replacement age is 2~3 years.
It is advisory to replace the fan when abnormal noise or even vibration occurred to the
fan due to bearing wear and fan blade aging. The standard replacement age is 2~3 years.
Filter Electrolytic CapacitorFilter Electrolytic Capacitor
The performance of filter electrolytic capacitor is subject to the pulsating current of main circuit. High ambient temperature or frequent load jump may cause damage to the filter electrolytic capacitor. Generally, every 10 rise in temperature may lead to reduction of the capacitor's service life by half (as shown in Fig. 8-1). If there is any electrolytic leakage or safety valve emission, just replace it at once. The standard replacement age for electrolytic capacitor is 4~5 years.
The performance of filter electrolytic capacitor is subject to the pulsating current of main circuit. High ambient temperature or frequent load jump may cause damage to the filter electrolytic capacitor. Generally, every 10 rise in temperature may lead to reduction of the capacitor's service life by half (as shown in Fig. 8-1). If there is any electrolytic leakage or safety valve emission, just replace it at once. The standard replacement age for electrolytic capacitor is 4~5 years.
Fig. 8-1 Capacitor Life CurveFig. 8-1 Capacitor Life Curve
Ambient temperatureAmbient temperature
Running 12 hours per dayRunning 12 hours per day
Capacitor life (years)Capacitor life (years)
3 The above replacement duration for inverter's wearing parts is applied to the following conditions:3 The above replacement duration for inverter's wearing parts is applied to the following conditions:
.
Ambient Temperature: 30 averagely all year round.
Load Proportion: <85%
Operation Time: 12h/day.
If used beyond the above-mention range, the life of inverter's wearing parts will
minimize.
Ambient Temperature: 30 averagely all year round.
Load Proportion: <85%.
Operation Time: 12h/day.
If used beyond the above-mention range, the life of inverter's wearing parts will
minimize.
Chapter 8 Inverter Inspection and MaintenanceChapter 8 Inverter Inspection and Maintenance Chapter 8 Inverter Inspection and MaintenanceChapter 8 Inverter Inspection and Maintenance
Item Inspected CriteriaCriteriaInspection CycleInspection Cycle
Inspection Method
Resistor
Fan
PCB
FPC strand socket
Overall
LED
Connecting cable strand
RegularRegular
RegularRegular
RegularRegular
RegularRegular
RegularRegular
RegularRegular
Scent or audioScent or audio
Visual
Visual
Visual
Visual
Visual
AudioIs there any abnormal noise or vibration?
Normal sound and stable vibration.
Is the dust cleaned? Neat and clean.
Is it loose? RegularRegular No loose connection.
Is there any special odor or discoloring?
Is there any crack?
No odor and discoloring
No crack, smooth surface.
Is LED display normal?
Is there any scratch?
Is it firmly connected?
No scratched surface.
No loose connection.
Storage of InverterStorage of Inverter
Please pay attention to the following points if an inverter is set aside or stored for a short/long period:Please pay attention to the following points if an inverter is set aside or stored for a short/long period:
CAUTIONCAUTION
Chapter 8 Inverter Inspection and MaintenanceChapter 8 Inverter Inspection and Maintenance
DO not keep the inverter in a place with high temperature, humidity, heavy dust, metal shavings, corrosive gas and vibration, and ensure a good ventilation.
Long-term idle of the inverter may cause decreasing in filter characteristic of the electrolytic capacitor. So it should be recharged in half a year and the recharging period should be at least 1~2 hours. DO raise the voltage gradually by using a voltage regulator to some rated value before it is recharged. At the same time, check whether the inverter s function is normal or not, whether there is a short circuit caused by some problems. In case the above problems occur, just remove or seek service as soon as possible.
Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions
Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions
9.1 Inverter Outline Dimensions & Mounting Dimensions9.1 Inverter Outline Dimensions & Mounting Dimensions
ZVF9-0015T4ZVF9-0015T41.5KW 380V 3PH1.5KW 380V 3PH
MODE SHIFT
ENTERJOG REV
RUNSTOP
RESET
Hz A V FWD REV
CAUTICN
WARNING
High voltage insideHigh voltage inside
Read the user's manual.Do not connect AC power to out put terminals UVW.Do not open the cover while power is applied or at least 10 minutes after power has been removed.
Fig. 9-1 Inverter Model A Dimensional DrawingsFig. 9-1 Inverter Model A Dimensional Drawings
Inverter ModelsInverter ModelsPowerPower DimensionDimension
FigureFigure
Gross WeightGross
Weight
ZVF9-G0007T2/S2
ZVF9-G0015T2/S2
ZVF9-G0022S2
ZVF9-G0007T4
ZVF9-G0015T4/P0015T4
ZVF9-G0022T4/P0022T4
ZVF9-P0037T4
ZVF9-G0007T2/S2
ZVF9-G0015T2/S2
ZVF9-G0022S2
ZVF9-G0007T4
ZVF9-G0015T4/P0015T4
ZVF9-G0022T4/P0022T4
ZVF9-P0037T4
Fig.9-1 Fig.9-1
ZVF9-G0022T2
ZVF9-G0037T2/S2
ZVF9-G0037T4/P0037T4
ZVF9-G0040T4/P0040T4
ZVF9-G0055T4/P0055T4
ZVF9-P0075T4
ZVF9-G0022T2
ZVF9-G0037T2/S2
ZVF9-G0037T4/P0037T4
ZVF9-G0040T4/P0040T4
ZVF9-G0055T4/P0055T4
ZVF9-P0075T4
2.2
3.7
3.7
4.0
5.5
7.5
2.2
3.7
3.7
4.0
5.5
7.5
Fig.9-1 Fig.9-1
MODE
REV
JOGRUN
FUNC
DATA
STOP
RESET
SHIFT
Hz A V FWD REV
ZVF9-GO150T4ZVF9-GO150T415KW 380V 3PH15KW 380V 3PH
CAUTICNHigh voltage insideHigh voltage inside
WARNINGRead the u ser's manual.Do not connect AC power to output terminals UVW.Do not open the cover while power is applied orat least 10 minutes after power has been removed.
Fig. 9-2 Inverter Model B Dimensional DrawingsFig. 9-2 Inverter Model B Dimensional Drawings
Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions
Inverter ModelsInverter ModelsPowerPower DimensionDimension
FigureFigure
Gross WeightGross
Weight
3.5
Fig.9-3
Fig.9-3
Fig.9-3
Fig.9-3
CAUTICNCAUTICNHigh voltage insideHigh voltage inside
WARNINGWARNINGRead the u ser's manual.Read the u ser's manual.Do not connect AC power to output terminals UVW.Do not connect AC power to output terminals UVW.Do not open the cover while power is applied orDo not open the cover while power is applied orat least 10 minutes after power has been removed.at least 10 minutes after power has been removed.
MODEMODE
REV
JOG
REV
JOGRUNRUN
FUNC
DATA
FUNC
DATA
STOPSTOP
RESETRESET
SHIFTSHIFT
Hz Hz A A V V FWD FWD REVREV
HH
-124--124-
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
Fig.9-2
336 336 316 316 180 180 140 140 168 168 1010
380 380 360 360 210 210 160 160 200200 1010
470 470 450 450 270 270 206 206 246 246 1010
630 630 605 605 360 360 270 270 290 290 1010
1212
Inverter ModelsInverter ModelsPowerPower DimensionDimension
FigureFigure
Gross WeightGross
Weight
Inverter ModelsInverter ModelsPowerPower DimensionDimension
FigureFigure
Gross WeightGross
Weight
Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions
Fig. 9-3 Inverter Model B Dimensional DrawingsFig. 9-3 Inverter Model B Dimensional Drawings
1270
1700
1270
1700
574
710
574
710
380
410
380
410750 750 725725 470 470 370 370 345345
Fig. 9-5 ZR02 Operator Panel Dimensional DrawingsFig. 9-5 ZR02 Operator Panel Dimensional Drawings
When ZR02 operator panel needs an outlet installation, the mounting
dimension for mounting hole location shall be 69 (width) 117 (height).
When ZR02 operator panel needs an outlet installation, the mounting
dimension for mounting hole location shall be 69 (width) 117 (height).
9.2 Operator Panel Outline Dimensions & Mounting Dimensions9.2 Operator Panel Outline Dimensions & Mounting Dimensions
Fig. 9-4 ZR01 Operator Panel Dimensional DrawingsFig. 9-4 ZR01 Operator Panel Dimensional Drawings
TIPSTIPS
When ZR01 operator panel needs an outlet installation, an
extra operator panel mounting shall be used.
The Mounting dimension for mounting hole location shall be
60 (width) 72 (height).
When ZR01 operator panel needs an outlet installation, an
extra operator panel mounting shall be used.
The Mounting dimension for mounting hole location shall be
60 (width) 72 (height).
Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions Chapter 9 Outline Dimensions & Mounting DimensionsChapter 9 Outline Dimensions & Mounting Dimensions
Chapter 10 Quality WarrantyChapter 10 Quality Warranty
Chapter 10 Quality WarrantyChapter 10 Quality Warranty
1. Warranty Period Under Normal Conditions
We provide guarantees for repair, replacement and return of the purchase in 1 month
from the date of use.
We provide guarantees for repair and replacement in 3 months from the date of use.
We provide guarantee for repair in 12 months from the date of use.
2. If the date of use can not be verified, then the warranty period shall be 18 months from
the date of manufacture. Service exceeding the warranty period shall be charged to the
purchaser. The purchaser enjoys life-long paid service whenever and wherever he uses
an inverter made in our company.
3. Service in the following cases, even within the warranty period, shall be charged to the
purchaser:
Damage caused by mal-operation in violation of this manual;
Damage caused by improper use of an inverter that is off technical standard and
requirement;
Malfunction or damage caused by fire, earthquake, flood, abnormal input voltage or
other natural disasters;
Artificial damage caused by unauthorized repair or renovation;
Induced failure or aging of the device due to poor ambient;
Delayed or unsatisfied payment in violation of purchase appointment;
Unidentifiable nameplate, mark and date of manufacture
Malfunction or damage caused by improper transit or storage after purchase;
Fail to give an objective description on the use of installation, wiring, operation,
maintenance or else;
Defective products should be sent to us for repair, replacement and return, which can
be proceeded only after verifying the burden of liability.
4. In case there is any quality problem or accident, we merely promise to bear the above-
mentioned responsibilities. If a user needs more guarantees for liabilities, please assure
on the insurance company voluntarily.
1. Warranty Period Under Normal Conditions
We provide guarantees for repair, replacement and return of the purchase in 1 month
from the date of use.
We provide guarantees for repair and replacement in 3 months from the date of use.
We provide guarantee for repair in 12 months from the date of use.
2. If the date of use can not be verified, then the warranty period shall be 18 months from
the date of manufacture. Service exceeding the warranty period shall be charged to the
purchaser. The purchaser enjoys life-long paid service whenever and wherever he uses
an inverter made in our company.
3. Service in the following cases, even within the warranty period, shall be charged to the
purchaser:
Damage caused by mal-operation in violation of this manual;
Damage caused by improper use of an inverter that is off technical standard and
requirement;
Malfunction or damage caused by fire, earthquake, flood, abnormal input voltage or
other natural disasters;
Artificial damage caused by unauthorized repair or renovation;
Induced failure or aging of the device due to poor ambient;
Delayed or unsatisfied payment in violation of purchase appointment;
Unidentifiable nameplate, mark and date of manufacture
Malfunction or damage caused by improper transit or storage after purchase;
Fail to give an objective description on the use of installation, wiring, operation,
maintenance or else;
Defective products should be sent to us for repair, replacement and return, which can
be proceeded only after verifying the burden of liability.
4. In case there is any quality problem or accident, we merely promise to bear the above-
mentioned responsibilities. If a user needs more guarantees for liabilities, please assure
on the insurance company voluntarily.
10.1Inverter Quality Warranty10.1Inverter Quality Warranty
Appendix 1 Optional PartsAppendix 1 Optional Parts
Appendix 1 Optional PartsAppendix 1 Optional Parts
All the optional parts can be ordered for with us if needed.All the optional parts can be ordered for with us if needed.
1. Brake Assembly1. Brake Assembly
The brake assembly consists of two parts: braking unit and braking resistor. It is
necessary to install a brake assembly on the occasion that quick stop is required
though there is a heavy potential load (e.g., elevator) or inertia load.
The brake assembly consists of two parts: braking unit and braking resistor. It is
necessary to install a brake assembly on the occasion that quick stop is required
though there is a heavy potential load (e.g., elevator) or inertia load.
Fig. Appendix 1-1 Brake Assembly Wiring DiagramFig. Appendix 1-1 Brake Assembly Wiring Diagram
ZVF9-G0150T4 and the machine type under this model number provide built-in braking units in the machine. If the braking torque provided by internal braking assembly is not enough, then an external braking resistor can be fitted.When installing a brake assembly, DO take into consideration of the safety of surrounding ambient.For detailed parameters and introduction to the function, please refer to Brake Assembly User's Manual.
ZVF9-G0150T4 and the machine type under this model number provide built-in braking units in the machine. If the braking torque provided by internal braking assembly is not enough, then an external braking resistor can be fitted.When installing a brake assembly, DO take into consideration of the safety of surrounding ambient.For detailed parameters and introduction to the function, please refer to Brake Assembly User's Manual.
ll
ll
ll
Table Appendix 1-1 Recommended Brake Assembly Matching SpecificationsTable Appendix 1-1 Recommended Brake Assembly Matching Specifications
I n v e r t e r I n v e r t e r B r a k i n g U n i t B r a k i n g U n i t B r a k i n g R e s i s t a n c eB r a k i n g R e s i s t a n c e
VoltageVoltage MotorMotor ModelModel QuantityQuantityRecommended resistance valueRecommended resistance value
Resistor specificationResistor specification
Appendix 1 Optional PartsAppendix 1 Optional Parts
QuantityQuantity
Appendix EMI PreventionAppendix EMI Prevention
Appendix 2 EMC PreventionAppendix 2 EMC Prevention
Appendix Table 1: Inverter System EMC PreventionAppendix Table 1: Inverter System EMC Prevention
:
Power supply input cable
The distortion of power grid waveform caused by superimposed higher
harmonic current arisen out of nonlinear rectifier circuit to source impedance may
lead to interference over other electrical equipment under the same power grid. This
kind of interference is named type A interference.
The power current and higher harmonic current brings in alternating
electromagnetic field around the circuit cable, which results in electric field coupling
and magnetic flux inductive coupling to the nearer parallel cable such as the
communication cable, small signal transmission cable and etc. This kind of
interference is named type C or C interference.
Due to antenna effect of the cable's shielding layer, interference may be
produced over external wireless installation. This kind of interference is named type
B interference.
Power supply input cable:
The distortion of power grid waveform caused by superimposed higher
harmonic current arisen out of nonlinear rectifier circuit to source impedance may
lead to interference over other electrical equipment under the same power grid. This
kind of interference is named type A interference.
The power current and higher harmonic current brings in alternating
electromagnetic field around the circuit cable, which results in electric field coupling
and magnetic flux inductive coupling to the nearer parallel cable such as the
communication cable, small signal transmission cable and etc. This kind of
interference is named type C or C interference.
Due to antenna effect of the cable's shielding layer, interference may be
produced over external wireless installation. This kind of interference is named type
B interference.
1 EMI Types and propagation mode1 EMI Types and propagation mode
2 Inverter System EMC Solutions2 Inverter System EMC Solutions
Type Type
Conducted interference AConducted interference A
Radiated interference B:Radiated interference B:
Induction interference CInduction interference C
Remote-operated adapter and extended cableRemote-operated adapter and extended cable
There are two selection modes for remote operation on ZVF9 inverter. If it is
operated at short range 15m , just extend the shielding cable directly and
connect it to the operator panel. The company can provide a range of extended
shielding cables with different specifications such as 1m, 1.5m, 2m, 5m and 10m. If
there is any special requirement on cable length, just place an order with the
company.
There are two selection modes for remote operation on ZVF9 inverter. If it is
operated at short range 15m , just extend the shielding cable directly and
connect it to the operator panel. The company can provide a range of extended
shielding cables with different specifications such as 1m, 1.5m, 2m, 5m and 10m. If
there is any special requirement on cable length, just place an order with the
company.
ll
DO disconnect the power when performing a remote-operated wiring.DO disconnect the power when performing a remote-operated wiring.
Proceed in accordance with the methods described in Clause 3.2.2 in this manual. Proceed in accordance with the methods described in Clause 3.2.2 in this manual.
The standard machine type of ZVF9 inverter does not provide RS232 and RS485
communication function. User shall mark out the function at the time of order. The
control terminals of standard RS232 and RS485 communication interface may
connect to RS232 or RS485 communication cable to realize network control or ratio
interlocking control.
RS232 and RS485 serial communication protocol for ZVF9 inverter can be
operated under Windows98/2000. Other monitoring software for this series, featured
by friendly man-machine operation interface, can easily realize networking operation
and perform monitoring and other functions of the inverter. Please contact the service
center of this company or its agents if it is needed.
The standard machine type of ZVF9 inverter does not provide RS232 and RS485
communication function. User shall mark out the function at the time of order. The
control terminals of standard RS232 and RS485 communication interface may
connect to RS232 or RS485 communication cable to realize network control or ratio
interlocking control.
RS232 and RS485 serial communication protocol for ZVF9 inverter can be
operated under Windows98/2000. Other monitoring software for this series, featured
by friendly man-machine operation interface, can easily realize networking operation
and perform monitoring and other functions of the inverter. Please contact the service
center of this company or its agents if it is needed.
Appendix 1 Optional PartsAppendix 1 Optional Parts
The electromagnetic environment is very complicated in industrial occasions.
Besides, the inverter's working principle also decides that EMC exists in the
inverter itself. So it is very important to solve EMC problems effectively to ensure
reliable running of the system in such a comprehensive condition. In this chapter,
we give a research on EMC and provide corresponding solutions to EMC, in hope
of being helpful to you to solve practical problems.
Propagation mode
Common-base impedance coupling
Common source impedance couplingCommon source impedance coupling
Near field coupling
Farness field coupling
Near field coupling
Farness field coupling
Magnetic field coupling
Magnetic field induction
coupling
Remote Control Instruction Remote Control Instruction
Twisted pairTwisted pair
This type of interference can be suppressed by a good earth ground of the cable's
shielding layer or by installing a wireless noise filter (i.e., a ferrite bead).
Inverter Body
The leakage of high frequency electromagnetic field (EMF) produced by the high
speed switch of the power elements inside the inverter through the inverter's metal slit
can result in radiated interference over external wireless installation. This kind of
interference is named type B interference.
When other electrical equipment (including other inverters) share the same ground
with this inverter, then type A interference will be produced over other equipment if
the ground wire impedance is high at this time.
This type of interference can be suppressed by a good earth ground of the cable's
shielding layer or by installing a wireless noise filter (i.e., a ferrite bead).
Inverter Body
The leakage of high frequency electromagnetic field (EMF) produced by the high
speed switch of the power elements inside the inverter through the inverter's metal slit
can result in radiated interference over external wireless installation. This kind of
interference is named type B interference.
When other electrical equipment (including other inverters) share the same ground
with this inverter, then type A interference will be produced over other equipment if
the ground wire impedance is high at this time.
Wireless installationWireless installation
Other electrical equipment sharing the same ground wire with this inverter
Other electrical equipment sharing the same ground wire with this inverter
Solutions
This type of interference can be suppressed by installing an EMC power supply
filter or isolation transformer in the power supply input side.
This type of interference can be suppressed through well ordered wiring or
shielding. For example, the signal cable may adopt shielded wire and the shielding
layer shall be firmly grounded to reduce magnetic flux inductive coupling and
electric field coupling. The signal cable should be at least 100mm away from the
power cable. If the signal wire and the power cable intersect, please intersect
orthogonally. Generally speaking, it is not advisory to use an overlong signal wire. If
the operation instruction is far from the inverter, then it is recommended to use an
intermediate relay to have a control over it, as shown in the figure below.
Solutions
This type of interference can be suppressed by installing an EMC power supply
filter or isolation transformer in the power supply input side.
This type of interference can be suppressed through well ordered wiring or
shielding. For example, the signal cable may adopt shielded wire and the shielding
layer shall be firmly grounded to reduce magnetic flux inductive coupling and
electric field coupling. The signal cable should be at least 100mm away from the
power cable. If the signal wire and the power cable intersect, please intersect
orthogonally. Generally speaking, it is not advisory to use an overlong signal wire. If
the operation instruction is far from the inverter, then it is recommended to use an
intermediate relay to have a control over it, as shown in the figure below.
Communication equipment Communication equipment
Communication cableCommunication cable
Small signal transfer cable Small signal transfer cable
Industrial meterIndustrial meter
Wireless installationWireless installation
Other electronic equipmentOther electronic equipment
vercloseverclose
Appendix EMI PreventionAppendix EMI PreventionAppendix EMI PreventionAppendix EMI Prevention
Propagation Diagram of Input Cable's Interference over External Equipment
Propagation Diagram of Inverter Body's Interference over External Equipment
SolutionsType B interference can be suppressed by a good earth ground of the inverter
housing or by installing the inverter in a well-shielded metal cabinet. Generally, radiated interference produced by the inverter body has less influence on the external equipment.
It is recommended that other equipment had better connect to the ground through an independent ground wire and share the same or different point beyond the earth electrode with the inverter, as shown in the figure below.
Other equipmentOther equipment
Motor Cable The electromagnetic field (EMF) caused by fundamental current has weaker effect on electric field coupling and magnetic flux inductive coupling of the parallel cable. While the EMF produced by the higher harmonic current has stronger effect on electric field coupling.
Radiated interferenceDue to the existence of distributed capacity, there is high frequency earth leakage
current and interphase leakage current in the cable, which may lead to malfunction of some leakage protection devices such as circuit breaker, relay and other equipment. DO attach importance to these things.
Motor Cable The electromagnetic field (EMF) caused by fundamental current has weaker effect on electric field coupling and magnetic flux inductive coupling of the parallel cable. While the EMF produced by the higher harmonic current has stronger effect on electric field coupling. Radiated interference Due to the existence of distributed capacity, there is high frequency earth leakage current and interphase leakage current in the cable, which may lead to malfunction of some leakage protection devices such as circuit breaker, relay and other equipment. DO attach importance to these things.
Wireless installationWireless installation
Small signal transmission cableSmall signal transmission cable
Industrial InstrumentsIndustrial Instruments
Other electrical equipment sharing the same ground wire with the motor
Other electrical equipment sharing the same ground wire with the motor
Relay, contactor and other electromechanical elements
Instantaneous current and voltage surge will be caused by the close and open of the
switch devices such as relay, contactor and etc, which may result in discharging
radiation and conductive surge noise. This instantaneous noise must be prevented
when designing the peripheral circuit of the inverter, as shown in the figure below.
Relay, contactor and other electromechanical elements
Instantaneous current and voltage surge will be caused by the close and open of the
switch devices such as relay, contactor and etc, which may result in discharging
radiation and conductive surge noise. This instantaneous noise must be prevented
when designing the peripheral circuit of the inverter, as shown in the figure below.
Appendix EMI PreventionAppendix EMI PreventionAppendix EMI PreventionAppendix EMI Prevention
Propagation Diagram of Motor Cable's Interference over External EquipmentSolutions The basic solutions are the same with the defense of electromagnetic countermeasures of a power cable. Install an output wireless noise filter and keep the sensitive equipment away from the motor cable; or the motor cable adopts a well grounded shielded cable and insert this cable in a metal pipe.
Use an insensitive leakage protection breaker for the inverter system only; reduce carrier frequency of the inverter; or use an AC (output) reactor to solve this kind of problems.
Propagation Diagram of Motor Cable's Interference over External EquipmentSolutions The basic solutions are the same with the defense of electromagnetic countermeasures of a power cable. Install an output wireless noise filter and keep the sensitive equipment away from the motor cable; or the motor cable adopts a well grounded shielded cable and insert this cable in a metal pipe. Use an insensitive leakage protection breaker for the inverter system only; reduce carrier frequency of the inverter; or use an AC (output) reactor to solve this kind of problems.
As for a 24VDC controlled relay, a shunt winding continuous current diode
should be inserted at both ends of the coil and pay attention to the polarity of diode.
As for a 220VAC controlled contactor, an over-voltage suppressor should be
mounted at both ends of the coil (i.e., RC network). Also, the protection of switch
contact can not be ignored. This can be realized by forming a shunt winding RC or
RCD buffered network, as shown in the figure below.
As for a 24VDC controlled relay, a shunt winding continuous current diode
should be inserted at both ends of the coil and pay attention to the polarity of diode.
As for a 220VAC controlled contactor, an over-voltage suppressor should be
mounted at both ends of the coil (i.e., RC network). Also, the protection of switch
contact can not be ignored. This can be realized by forming a shunt winding RC or
RCD buffered network, as shown in the figure below.
Attached Table II: Conventional Symbols IllustrationAttached Table II: Conventional Symbols Illustration
No. No. NameName Figure SymbolFigure Symbol
Appendix EMI PreventionAppendix EMI Prevention
No. No. NameName Figure SymbolFigure Symbol
AC motor Frequency meter
Wattmeter Signal light
Ammeter Voltmeter
Main circuit terminal
Control loop terminal
ContactorCircuit breaker
Thermal relay Relay coil
Reactor Operational amplifier
Diode Optoelectronic coupler
Switch DC power supply
Non-polar capacitor Polar capacitor
Triode (NPN type)
Discharge tube Piezo-resistor
Triode (PNP type)
Resistor Potentiometer
Appendix 3 User's Parameter Amendment RecordAppendix 3 User's Parameter Amendment Record
Appendix 3 User's Parameter Amendment RecordAppendix 3 User's Parameter Amendment Record
Table Appendix 3-1 User's Parameter Amendment RecordTable Appendix 3-1 User's Parameter Amendment Record
User
Setting
User
Setting
Factory Default Setting
Factory Default Setting
Function CodeFunction Code
Factory Default Setting
Factory Default Setting
Function CodeFunction Code
Software Version numberSoftware Version number
Inverter Specification DisplayInverter Specification Display
Parameter Initiating / Removing Failure RecordParameter Initiating / Removing Failure Record
Selection of frequency setting mannerSelection of frequency setting manner
Selection of operation control modeSelection of operation control mode
Selection of motor rotating directionSelection of motor rotating direction
Maximum output frequencyMaximum output frequency
Selection of V/F curve modeSelection of V/F curve mode
Selection of acceleration /deceleration mannerSelection of acceleration /deceleration manner
Accelerating period 1Accelerating period 1
Decelerating period 1Decelerating period 1
Upper limit of frequencyUpper limit of frequency
Lower limit of frequencyLower limit of frequency
RemainRemain
Jog running frequency
Jog accelerating period
Jog decelerating period
Jog running frequency
Jog accelerating period
Jog decelerating period
Selection of starting modeSelection of starting mode
Halt modeHalt mode
Starting frequency
Maintaining period of starting frequency
Starting DC braking voltage
Starting DC braking period
FWD/REV dead time
Stop dc braking starting Frequency
Stop DC braking voltage
Stop DC braking period
Remain
Selection of Power On display itemsSelection of Power On display items
RemainRemain
Display coefficient of linear speed
Display coefficient of linear speed
Displaycoefficient of closed-loop control
Display coefficient of closed-loop controlSelection of REV/JOG key functionSelection of REV/JOG key function
Two-wire/Three-wire running controlTwo-wire/Three-wire running control
Accelerating period 2Accelerating period 2
Decelerating period 2Decelerating period 2
RemainRemain
RemainRemain
RemainRemain
Selection of automatic energy-saving operation
Setting of slip compensation
Selection of AVR function
Torque lifting
Carrier frequency
Leap frequency 1
Range of leap frequency 1
Leap frequency 2
Range of leap frequency 2
Reference frequency of acceleration/deceleration period
Selection of restart after instant blackout
Wait time for restart after instant blackout
Frequency arrival checkout range (FAR)
Appendix 3 User's Parameter Amendment RecordAppendix 3 User's Parameter Amendment Record
User
Setting
User
Setting
Setting of FDT level
FDT lagged value
Overload pre-alarm level
Overload pre-alarm action period
F062-063
Function CodeFunction Code
Function NameFactory Default Setting
Factory Default Setting
Function CodeFunction Code
Factory Default Setting
Factory Default Setting
Lower limit of analog voltage input
Upper limit of analog voltage input
Lower limit of analog current IUpper limit of analog current I
Bipolarity zero offset of analog input
Biasing direction of the frequency corresponding to the lower limit of analog input
Biasing direction of the frequency corresponding to the Upper limit of analog input
Corresponding set frequency of Min. analog input
Corresponding set frequency of Max. analog input
Delay period of analog input signal
10V Analog Meter Output AM
Analog Meter Output AM Proportional Gain
Analog Meter Output AM Bias
Analog input assembly settingAnalog input assembly setting
Remain
Remain
Selection of programmable multistage speed running
Output frequency at the first stage speed
Output frequency at the second stage speed
Output frequency at the third stage speed
Output frequency at the fifth stage speed
Output frequency at the fourth stage speed
Output frequency at the sixth stage speed
Output frequency at the seventh stage speed
First stage speed running time
Selection of running direction at the first stage speed
Selection of running direction at the second stage speed
Selection of running direction at the third stage speed
Selection of running direction at the fourth stage speed
Selection of running direction at the first stage speed
Selection of running direction at the sixth stage speed
Selection of running direction at the seventh stage speed
First Stage Speed Add-Subtract TimeRunning time at the second stage speed
Third stage speed running time
fourth stage speed running time
Fifth stage speed running time
Sixth stage speed running time
Seventh stage speed running time
Remain
Remain
Remain
Function selection of multi-function input terminal X1Function selection of multi-function input terminal X1
Function selection of multi-function input terminal X2Function selection of multi-function input terminal X2
Function selection of multi-function input terminal X3Function selection of multi-function input terminal X3
Function selection of multi-function input terminal X4Function selection of multi-function input terminal X4Function selection of multi-function input terminal X5Function selection of multi-function input terminal X5
Function selection of multi-function input terminal X6Function selection of multi-function input terminal X6
In accordance with specifications
User
Setting
User
Setting
User
Setting
User
SettingFunction Name
Function NameFunction Name
Function selection of collector output terminal Y1Function selection of collector output terminal Y1Function selection of collector output terminal Y2Function selection of collector output terminal Y2
RemainRemain
Selection of counting modesSelection of counting modes
RemainRemain
In accordance with specifications
In accordance with specifications
Second Stage Speed Add-Subtract Time
Third Stage Speed Add-Subtract Time
Fourth Stage Speed Add-Subtract Time
Fifth Stage Speed Add-Subtract Time
Sixth Stage Speed Add-Subtract Time
Seventh Stage Speed Add-Subtract Time
Appendix 4 WarrantyAppendix 4 Warranty
Appendix 4 User's WarrantyAppendix 4 User's Warranty
Maintenance RecordMaintenance Record
User's DetailsUser's Details
Failure CauseFailure Cause
SettlementSettlement
Date of MaintenanceDate of Maintenance Serviceman SignatureServiceman Signature
Failure CauseFailure Cause
l This copy is for the holder (user) only.This copy is for the holder (user) only.
Name of Distributor
Date of Purchasing
Inverter Model(s)
Identification Number
Name of Equipment
Power Capability of the Motor
Date of Installation Date of Use
SettlementSettlement
Date of MaintenanceDate of Maintenance Serviceman SignitureServiceman Signiture
Appendix 3 User's Parameter Amendment RecordAppendix 3 User's Parameter Amendment Record
User
Setting
User
Setting
Factory Default Setting
Factory Default Setting
Function CodeFunction Code
Factory Default Setting
Factory Default Setting
Function CodeFunction Code
User
Setting
User
SettingFunction NameFunction Name
Counting valueCounting value
Counting coefficientCounting coefficient
Count to option processingCount to option processing
RemainRemain
Motor rated rotating speedMotor rated rotating speed
PID action selectionPID action selection
Selection of PID target value setting modeSelection of PID target value setting mode
PID target value settingPID target value setting
Selection of feedback conditions
Selection of feedback conditions
PID feedback flow gainPID feedback flow gain
PID feedback polarity selectionPID feedback polarity selection
Proportional gain (P)Proportional gain (P)
Integral time constant TIIntegral time constant TI
Differential time constant DIDifferential time constant DI
Motor rated frequencyMotor rated frequency
Motor rated voltageMotor rated voltage
Motor rated currentMotor rated current
Revoke thresholdRevoke threshold
Overload & overheat protection methodOverload & overheat protection method
Check-out timefor sleep/revoke threshold
Check-out time for sleep/revoke threshold
Inverter input open-phase protection Inverter input open-phase protection
Over-voltage stall proof functionOver-voltage stall proof function
Motor thermal relay protection coefficientMotor thermal relay protection coefficient
Selection of automatic curre nt-limiting functionSelection of automatic curre nt-limiting functionAcceleration over-current stall proof levelAcceleration over-current stall proof levelConstant speed over-current stall proof levelConstant speed over-current stall proof level
Failure self-resetting timesFailure self-resetting times
Failure self-resetting intervalFailure self-resetting interval
RemainRemain
RemainRemain
Sampling periodSampling period
Deviation limitDeviation limit
Sleep thresholdSleep threshold
COM addressCOM address
COM data formCOM data form
COM baud rateCOM baud rate
Selection of COM linking ratioSelection of COM linking ratio
Selection of parameter protectionSelection of parameter protection
Remain
Actual running time (S)
Actual running time (H)
Frequency power failure memory
Ventilator fan control
PWM adaptive control
In accordance with specifications
Inverter User's WarrantyInverter User's Warranty
User shall fill it out based on the facts with care and return it to us as soon as possible, so that we could serve you better to avoid inconvenience or loss caused by your improper installation or error use.
User shall fill it out based on the facts with care and return it to us as soon as possible, so that we could serve you better to avoid inconvenience or loss caused by your improper installation or error use.
User's DetailsUser's Details
Description of UseDescription of Use
Description of Parameter AmendmentDescription of Parameter Amendment
User's Work Unit Tel
Add. Post Code
Contact Person Department
Name of Distributor
ADD/TEL
Date of Purchasing Bill Number
Inverter Model(s)
Identification Number
Name of Equipment
Power Capability of the Motor
Date of Installation Date of Use
Appendix 4 WarrantyAppendix 4 Warranty